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Perspectives, frontiers, and new horizons for plasma-based space
electric propulsion

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Free
Published Online: 03 February 2020
Accepted: October 2019

Perspectives, frontiers, and new horizons for plasma-based space
electric propulsion editors-pick

Physics of Plasmas 27, 020601 (2020); https://doi.org/10.1063/
1.5109141
[orcid] I. Levchenko^1,2^,^a) , [orcid] S. Xu^1, [orcid] S. Mazouffre
^3, [orcid] D. Lev^4, [orcid] D. Pedrini^5, [orcid] D. Goebel^6, 
[orcid] L. Garrigues^7, [orcid] F. Taccogna^8, and [orcid] K. Bazaka^
1,2,9^,^a) 
more...View Affiliations

  * ^1Plasma Sources and Application Centre/Space Propulsion Centre
    Singapore, NIE, Nanyang Technological University, Singapore
    637616, Singapore
  * ^2School of Chemistry, Physics, and Mechanical Engineering,
    Queensland University of Technology, Brisbane, Australia
  * ^3Institut de Combustion, Aerothermique, Reactivite et
    Environnement (ICARE), CNRS--University of Orleans, 1C avenue de
    la Recherche Scientifique, 45071 Orleans, France
  * ^4Space Propulsion Systems Department, Rafael - Advanced Defense
    Systems Ltd., Haifa 3102102, Israel
  * ^5SITAEL, Space Division, Pisa 56121, Italy
  * ^6Jet Propulsion Laboratory, California Institute of Technology,
    Pasadena, California 91109, USA
  * ^7LAPLACE (Laboratoire Plasma et Conversion d'Energie),
    Universite de Toulouse, CNRS, UPS, INPT Toulouse 118, route de
    Narbonne, F-31062 Toulouse cedex 9, France
  * ^8Istituto per la Scienza e Tecnologia dei Plasmi, CNR, 70126
    Bari, Italy
  * ^9Research School of Electrical, Energy and Materials
    Engineering, The Australian National University, Canberra, ACT
    2601, Australia
  * ^a)Authors to whom correspondence should be addressed:
    [email protected] and [email protected]

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          o Space propulsion
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ABSTRACT

There are a number of pressing problems mankind is facing today that
could, at least in part, be resolved by space systems. These include
capabilities for fast and far-reaching telecommunication, surveying
of resources and climate, and sustaining global information networks,
to name but a few. Not surprisingly, increasing efforts are now
devoted to building a strong near-Earth satellite infrastructure,
with plans to extend the sphere of active life to orbital space and,
later, to the Moon and Mars if not further. The realization of these
aspirations demands novel and more efficient means of propulsion. At
present, it is not only the heavy launch systems that are fully
reliant on thermodynamic principles for propulsion. Satellites and
spacecraft still widely use gas-based thrusters or chemical engines
as their primary means of propulsion. Nonetheless, similar to other
transportation systems where the use of electrical platforms has
expanded rapidly, space propulsion technologies are also experiencing
a shift toward electric thrusters that do not feature the many
limitations intrinsic to the thermodynamic systems. Most importantly,
electric and plasma thrusters have a theoretical capacity to deliver
virtually any impulse, the latter being ultimately limited by the
speed of light. Rapid progress in the field driven by consolidated
efforts from industry and academia has brought all-electric space
systems closer to reality, yet there are still obstacles that need
addressing before we can take full advantage of this promising family
of propulsion technologies. In this paper, we briefly outline the
most recent successes in the development of plasma-based space
propulsion systems and present our view of future trends,
opportunities, and challenges in this rapidly growing field.
I. INTRODUCTION
Section:
[Choose                      ]
Previous sectionNext section
There is little doubt that the nanotechnological revolution has
reached and in effect underpinned the tremendous progress in space
technologies,^11. N. Kishi, " Management analysis for the space
industry," Space Policy 39-40, 1-6 (2017). https://doi.org/10.1016/
j.spacepol.2017.03.006 providing the much-needed technological
framework to not only build extensive near-Earth satellite networks
but also support ambitious aspirations for permanent lunar stations
and eventual colonization of Mars.^2-42. E. Musk, " Making humans a
multi-planetary species," New Space 5, 46-61 (2017). https://doi.org/
10.1089/space.2017.29009.emu3. S. Do, A. Owens, K. Ho, S. Schreiner,
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Keidar, and K. Bazaka, " Mars colonization: Beyond getting there,"
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gch2.201800062 As space assets become exceedingly smaller^55. I.
Levchenko, M. Keidar, J. Cantrell, Y.-L. Wu, H. Kuninaka, K. Bazaka,
and S. Xu, " Explore space using swarms of tiny satellites," Nature
562, 185 (2018). https://doi.org/10.1038/d41586-018-06957-2 and
utilize more advanced electronics and sensors, the need for advanced
space propulsion systems with the efficiency that matches that of
other satellite systems is becoming increasingly evident. Not
surprisingly, exploration of new physical principles for creating
thrust in space^6,76. I. Levchenko, K. Bazaka, S. Mazouffre, and S.
Xu, " Prospects and physical mechanisms for photonic space propulsion
," Nat. Photonics 12, 649-657 (2018). https://doi.org/10.1038/
s41566-018-0280-77. B. Beaurepaire, A. Vernier, M. Bocoum, F. Bohle,
A. Jullien, J.-P. Rousseau, T. Lefrou, D. Douillet, G. Iaquaniello,
R. Lopez-Martens, A. Lifschitz, and J. Faure, " Effect of the laser
wave front in a laser-plasma accelerator," Phys. Rev. X 5, 031012
(2015). https://doi.org/10.1103/PhysRevX.5.031012 and advanced
implementation of the existing thrust systems attract strong
attention of the researchers.^8,98. I. Levchenko, K. Bazaka, Y. Ding,
Y. Raitses, S. Mazouffre, T. Henning, P. J. Klar, S. Shinohara, J.
Schein, L. Garrigues, M. Kim, D. Lev, F. Taccogna, R. W. Boswell, C.
Charles, H. Koizumi, S. Yan, C. Scharlemann, M. Keidar, and S. Xu, " 
Space micropropulsion systems for Cubesats and small satellites: From
proximate targets to furthermost Frontiers," Appl. Phys. Rev. 5,
011104 (2018). https://doi.org/10.1063/1.50077349. K. Lemmer, " 
Propulsion for CubeSats," Acta Astronaut. 134, 231-243 (2017). https:
//doi.org/10.1016/j.actaastro.2017.01.048 Among the plethora of
available and emerging space propulsion systems, the thrust platforms
that utilize plasma^10-1310. I. Adamovich, S. D. Baalrud, A.
Bogaerts, P. J. Bruggeman, M. Cappelli, V. Colombo, U. Czarnetzki, U.
Ebert, J. G. Eden, P. Favia, D. B. Graves, S. Hamaguchi, G. Hieftje,
M. Hori, I. D. Kaganovich, U. Kortshagen, M. J. Kushner, N. J. Mason,
S. Mazouffre, S. M. Thagard, H.-R. Metelmann, A. Mizuno, E. Moreau,
A. B. Murphy, B. A. Niemira, G. S. Oehrlein, Z. L. Petrovic, L. C.
Pitchford, Y.-K. Pu, S. Rauf, O. Sakai, S. Samukawa, S.
Starikovskaia, J. Tennyson, K. Terashima, M. M. Turner, M. C. M. van
de Sanden, and A. VardelleHide, " The 2017 plasma roadmap: Low
temperature plasma science and technology," J. Phys. D: Appl. Phys.
50, 323001 (2017). https://doi.org/10.1088/1361-6463/aa76f511. L.
Dubois, F. Gaboriau, L. Liard, D. Harribey, C. Henaux, L. Garrigues,
G. J. H. Hagelaar, S. Mazouffre, C. Boniface, and J. P. Boeuf, " 
ID-HALL, a new double stage Hall thruster design. I. Principle and
hybrid model of ID-HALL," Phys. Plasmas 25, 093503 (2018). https://
doi.org/10.1063/1.504335412. K. Takase, K. Takahashi, and Y. Takao, "
Effects of neutral distribution and external magnetic field on plasma
momentum in electrodeless plasma thrusters," Phys. Plasmas 25, 023507
(2018). https://doi.org/10.1063/1.501593713. N. Tiwari, S. Bhandari,
and S. Ghorui, " Stability and structures in atmospheric pressure DC
non-transferred arc plasma jets of argon, nitrogen, and air," Phys.
Plasmas 25, 072103 (2018). https://doi.org/10.1063/1.5034397 and
ionized gas^14-1614. T. Furukawa, K. Shimura, D. Kuwahara, and S.
Shinohara, " Verification of azimuthal current generation employing a
rotating magnetic field plasma acceleration method in an open
magnetic field configuration," Phys. Plasmas 26, 033505 (2019).
https://doi.org/10.1063/1.506439215. J. Tian, W. Liu, Y. Gao, and L.
Zhao, " Discharge and metallic plasma generation characteristics of
an insulated anode with a micropore," Phys. Plasmas 26, 023511
(2019). https://doi.org/10.1063/1.507867716. L. Cheng, Y. Wang, W.
Ding, C. Ge, J. Yan, Y. Li, Z. Li, and A. Sun, " Experimental study
on the discharge ignition in a capillary discharge based pulsed
plasma thruster," Phys. Plasmas 25, 093512 (2018). https://doi.org/
10.1063/1.5038087 to create reactive thrust are currently attracting
the strongest attention due to many potential advantages of these
devices,^17-1917. C. Charles, " Plasmas for spacecraft propulsion,"
J. Phys. D: Appl. Phys. 42, 163001 (2009). https://doi.org/10.1088/
0022-3727/42/16/16300118. S. Mazouffre, " Electric propulsion for
satellites and spacecraft: Established technologies and novel
approaches," Plasma Sources Sci. Technol. 25, 033002 (2016). https://
doi.org/10.1088/0963-0252/25/3/03300219. K. Nakagawa, T. Tsuchiya,
and Y. Takao, " Microfabricated emitter array for an ionic liquid
electrospray thruster," Jpn. J. Appl. Phys. 56, 06GN18 (2017). https:
//doi.org/10.7567/JJAP.56.06GN18 particularly for their ability to
deliver a very high specific impulse^20,2120. L. Conde, J. L.
Domenech-Garret, J. M. Donoso, J. Damba, S. P. Tierno, E.
Alamillo-Gamboa, and M. A. Castillo, " Supersonic plasma beams with
controlled speed generated by the alternative low power hybrid ion
engine (ALPHIE) for space propulsion," Phys. Plasmas 24, 123514
(2017). https://doi.org/10.1063/1.500588121. Y. Ding, H. Su, P. Li,
L. Wei, H. Li, W. Peng, Y. Xu, H. Sun, and D. Yu, " Study of the
catastrophic Discharge phenomenon in a Hall thruster," Phys. Lett. A
381, 3482-3486 (2017). https://doi.org/10.1016/j.physleta.2017.09.002
and potentially long service life.^22,2322. Voyager 1 Fires Up
Thrusters After 37 Years; accessed June 2018.23. V. Croes, A. Tavant,
R. Lucken, R. Martorelli, T. Lafleur, A. Bourdon, and P. Chabert, " 
The effect of alternative propellants on the electron drift
instability in Hall-effect thrusters: Insight from 2D
particle-in-cell simulations," Phys. Plasmas 25, 063522 (2018).
https://doi.org/10.1063/1.5033492
However, further uptake of these systems is hindered by several
challenges. First of all, there is an urgent need to further enhance
the critically important operational parameters of these thrusters,
such as their energy efficiency and capability to adjust specific
impulse to the task at hand. This need holds true for all existing
and emerging electric and plasma propulsion systems when used on any
space asset--from a small satellite to a large spacecraft, including
those destined for manned missions to the Moon and Mars. Indeed, the
specific impulse of the electric propulsion system is, in most cases,
a mission-dependent parameter. Other related parameters, such as
thruster efficiency, are also critically important. For longer
missions, the delivery of greater specific impulse requires a greater
amount of energy for ion acceleration and thus an increased capacity
with respect to energy storage and other systems. As a result, the
specific impulse of an electric propulsion system will be determined
by the complex optimization of the whole mission design.^24,2524. K.
Kuriki, K. Ninomiya, M. Nagatomo, N. Tsuya, M. Kawachi, K. Ijichi,
and H. Kimura, " The design and orbital operation of space flyer unit
," Acta Astronaut. 24, 33-43 (1991). https://doi.org/10.1016/
0094-5765(91)90150-425. R. C. Koppel, " Optimal specific impulse of
electric propulsion," Proceedings of the 2nd European Spacecraft
Propulation Conference, Noordwijk, the Netherlands, edited by M.
Perry, 27-29 May 1997, pp. 131-139. It is worth noting that since the
propulsion needs typically change during the course of the mission,
there is strong interest in hybrid variable-specific-impulse electric
propulsion platforms to deliver greater efficiency.^26,2726. A.
Sasoh, H. Kasuga, Y. Nakagawa, T. Matsuba, D. Ichihara, and A.
Iwakawa, " Electrostatic-magnetic-hybrid thrust generation in
central-cathode electrostatic thruster (CC-EST)," Acta Astronaut. 152
, 137-145 (2018). https://doi.org/10.1016/j.actaastro.2018.07.05227.
E. Chesta, D. Estublier, B. Fallis, E. Gengembre, J. Gonzalez del
Amo, N. Kutufa, D. Nicolini, G. Saccoccia, L. Casalino, P. Dumazert 
et al., " Flexible variable-specific-impulse electric propulsion
systems for planetary missions," Acta Astronaut. 59, 931-945 (2006).
https://doi.org/10.1016/j.actaastro.2005.07.053
Second, the service life of the existing plasma thrusters is still
not sufficiently high, mainly due to very strong erosion of the
electrodes and accelerating channel walls by the action of highly
energetic ion, electron, and plasma fluxes impinging on the surface.^
28,2928. B. Karadag, S. Cho, and I. Funaki, " Thrust performance,
propellant ionization, and thruster erosion of an external discharge
plasma thruster," J. Appl. Phys. 123, 153302 (2018). https://doi.org/
10.1063/1.502382929. M. Meyer, M. Byrne, B. Jorns, and I. D. Boyd, " 
Erosion of a meshed reflector in the plume of a Hall effect thruster,
Part 1: Modeling," AIAA Paper 2019-3987, 2019. The heat, radiation,
and other effects that are present in the energy-loaded plasma thrust
systems may further contribute to the failure of materials that come
into direct contact with plasmas. Finally, the limitations of the
currently available plasma cathode systems still remain a critical
block that significantly hinders the total efficiency and reliability
of the entire space thrust system.
In this perspective, we will briefly outline the most recent
successes in the plasma-based space propulsion systems and present
our view on further trends, possibilities, and challenges facing
these plasma systems. For the purpose of this discussion, the entire
spectrum of the space electric propulsion platforms is subdivided
into three main types, namely, the electrostatic, electromagnetic,
and electrothermal systems. The electrostatic and electromagnetic
thrusters exploit the electric and magnetic fields for the
generation, acceleration, and expulsion of ionized propellant, and
hence, the articles discussing these platforms are represented well
in the Physics of Plasmas journal. In contrast, the electrothermal
thrusters feature mainly a thermodynamic principle of acceleration
via the electric current heating of the propellant, where the latter
then expands and thermodynamically accelerates through the nozzle.
When compared to the former two thruster types, the electrothermal
thrusters demonstrate significantly lower specific impulse levels
(see Fig. 3) and, as a consequence, are not a strong focus for the
Physics of Plasmas journal. Hence, in this this article, we will
mainly characterize the two main groups of thrusters, i.e., the
electrostatic and electromagnetic systems, as well as cathodes that
play an exceptionally important role in many various types of
thrusters, such as Hall-type and gridded ion systems. We will first
briefly characterize the major and most advanced types "of plasma-
and electric discharge-based space propulsion platforms," show their
level of development and challenges they are facing, and then set the
ways for the future development of this field in Sec. II. Moreover,
we will discuss two aspects of prime importance, namely, problems and
challenges linked to "miniaturization" of various electric propulsion
systems (Fig. 1) and advantages and opportunities provided by the
application of novel materials in this field. Finally, in Sec. IV, we
will set the longer-term goals and directions for this exciting
field. We aim our Perspective article at the most general physics
audience and students who may benefit from a comprehensive top-level
view of the present-day state of the art in the plasma propulsion as
a whole and see what opportunities, challenges and problems are there
to be considered in the nearest future. For the more specialized
expert audience, we will provide an extended (over 230 publications)
list of the most recent specialized textbooks and papers on the
topic.
figure
FIG. 1. A "planetary system" of electric propulsion thrusters. Four
main types of electric propulsion systems are considered as the most
promising candidates for various space applications. While Hall, ion,
and pulsed thrusters have already been tested and currently found
multiple applications as space propulsion systems, the
magnetoplasmadynamic (MPD) thruster was only once tested in a real
space flight in the framework of the EPEX (Electric Propulsion
EXperiment) mission onboard of the Japanese Space Flyer Unit project.
^2424. K. Kuriki, K. Ninomiya, M. Nagatomo, N. Tsuya, M. Kawachi, K.
Ijichi, and H. Kimura, " The design and orbital operation of space
flyer unit," Acta Astronaut. 24, 33-43 (1991). https://doi.org/
10.1016/0094-5765(91)90150-4 Nevertheless, MPD thrusters are
considered among the most promising propulsion systems for future
missions related to the colonization of Mars and the Moon. Reprinted
from Levchenko et al., Appl. Phys. Rev. 5, 011104 (2018). Copyright
2018 Author(s), licensed under a Creative Commons Attribution (CC BY)
license.^88. I. Levchenko, K. Bazaka, Y. Ding, Y. Raitses, S.
Mazouffre, T. Henning, P. J. Klar, S. Shinohara, J. Schein, L.
Garrigues, M. Kim, D. Lev, F. Taccogna, R. W. Boswell, C. Charles, H.
Koizumi, S. Yan, C. Scharlemann, M. Keidar, and S. Xu, " Space
micropropulsion systems for Cubesats and small satellites: From
proximate targets to furthermost Frontiers," Appl. Phys. Rev. 5,
011104 (2018). https://doi.org/10.1063/1.5007734

  * PPT|
  * High-resolution

The rest of this paper is organized as follows. In Sec. II, we will
first briefly outline the major types of the electric propulsion
systems and their key characteristics; this section aims to introduce
the field to the broader readership of the journal, including
students and the not-expert audience. Then, in the subsequent
subsections A, B, and C, we will analyze the challenges and
opportunities specific to the electrostatic systems, electrodynamic
systems, and cathode systems used for space electric propulsion
thrusters. Next, Sec. III will deal with the modeling and simulation
of the space electric propulsion systems, and, finally, Sec. IV will
outline the directions for future development of the field, briefly
touching on the emerging and prospective approaches.
A Hall thruster^3030. I. Kronhaus and A. Linossier, " Experimental
characterization of the narrow channel Hall thruster," Plasma Sources
Sci. Technol. 27, 124005 (2018). https://doi.org/10.1088/1361-6595/
aaec65 uses a number of externally mounted magnetic coils or a single
coil of a larger size surrounding the entire thruster. An internal
magnetic coil may also be used. An incandescent cathode and anode are
installed on the outside and inside of the acceleration channel,
respectively. The acceleration channel itself can be made out of
ceramic or a metal, with the latter configuration producing a
thruster with an anode layer. The anode is typically perforated, with
the holes used to supply the propellant, e.g., Xe, as shown in the
figure. Upon application of an electric potential to the cathode
relative to the anode, a closed Hall current is produced within the
channel, being controlled by the intersection of magnetic and
electric fields. A static electric field is used to accelerate
ionized propellant, whereas the magnetized electrons of the circular
Hall current diffuse in the direction of the anode. As Hall thrusters
are electrostatic ion accelerators, thrust they produce can be
described by considering the interaction of Hall current with the
externally applied magnetic field. An ion thruster (depicted on the
right) comprises a cylindrically shaped body housing a discharge
unit, i.e., an incandescent hollow cathode, an anode, and a magnetic
coil. Additional focusing magnetic coils are mounted on the outside
of the body. A unit consisting of internal and external grids is used
for extraction and acceleration, respectively. An additional cathode
unit is mounted on the outside of the acceleration channel and is
used to produce an electron flux to neutralize the ion exhaust as it
exits the channel in order to prevent charge accumulation on the
spacecraft. The propellant gas such as Xe is delivered into the
hollow cathode, at which point it undergoes ionization in the
magnetized discharge. The internal grid is then used to extract the
ion flux, which is then accelerated by the second grid. This results
in the ion flux exiting the thruster at high velocity.
II. SURVEY AND PERSPECTIVES: WHERE ARE WE WITH PLASMA PROPULSION?
Section:
[Choose                         ]
Previous sectionNext section
First of all, we should briefly consider what makes plasma propulsion
so promising. Newton's third law of motion postulates that in order
to generate thrust in space, an object must expel mass to gain
acceleration, with the force expressed as F = m x V[ex], where V[ex]
is the velocity with which mass is expelled relative to the object
and m is the rate at which mass is consumed to produce the force
(kilogram per second). At present, chemical rockets and electric
propulsion thrusters are the most typical systems for space
propulsion. Primarily used to deliver assets from Earth to space,
chemical rockets are characterized by much greater thrust-to-mass
ratio e reaching 2000 N kg^-1; however, the exhaust velocity of these
systems is comparatively low, at V[ex] = 5000 m s^-1 even for the
most efficient fuels. In contrast, systems that use electric
propulsion can deliver a greater exhaust velocity approaching 10^5
m s^-1 yet can only produce low levels of thrust. In these systems,
ions are accelerated using electric fields, and there are no physical
limitations to prevent further improvements in the value of V[ex] (
Fig. 2).
figure
FIG. 2. Why do we need to adjust the exhaust velocity? In order to
obtain the maximum efficiency for the most typical case of orbital
velocity, the thruster should be able to provide 8-12 km/s. This is
not easily achievable when using chemical thrusters yet a trivial
challenge for any plasma-based system. Moreover, when the exhaust
velocity V[e] is very high, the energy efficiency drops off weaker
than for the case when V[e] is low, as seen from the graph.

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When compared to thermodynamic (chemical) rocket engines that come
only in few modifications, plasma propulsion thrusters are
represented by a large and diverse family of platforms, which could
in principle produce thrust in space over a very wide range of power
(from fractions of watts to megawatts) and specific impulse (from
hundreds to tens of thousands of seconds), see Fig. 3 for a brief
classification and visual representation of the devices within the
power/impulse field. A more comprehensive picture and characteristics
of various types of space electric propulsion systems could be found
in the numerous recently published review papers.^6,8,9,17,18,31-366.
I. Levchenko, K. Bazaka, S. Mazouffre, and S. Xu, " Prospects and
physical mechanisms for photonic space propulsion," Nat. Photonics 12
, 649-657 (2018). https://doi.org/10.1038/s41566-018-0280-78. I.
Levchenko, K. Bazaka, Y. Ding, Y. Raitses, S. Mazouffre, T. Henning,
P. J. Klar, S. Shinohara, J. Schein, L. Garrigues, M. Kim, D. Lev, F.
Taccogna, R. W. Boswell, C. Charles, H. Koizumi, S. Yan, C.
Scharlemann, M. Keidar, and S. Xu, " Space micropropulsion systems
for Cubesats and small satellites: From proximate targets to
furthermost Frontiers," Appl. Phys. Rev. 5, 011104 (2018). https://
doi.org/10.1063/1.50077349. K. Lemmer, " Propulsion for CubeSats,"
Acta Astronaut. 134, 231-243 (2017). https://doi.org/10.1016/
j.actaastro.2017.01.04817. C. Charles, " Plasmas for spacecraft
propulsion," J. Phys. D: Appl. Phys. 42, 163001 (2009). https://
doi.org/10.1088/0022-3727/42/16/16300118. S. Mazouffre, " Electric
propulsion for satellites and spacecraft: Established technologies
and novel approaches," Plasma Sources Sci. Technol. 25, 033002
(2016). https://doi.org/10.1088/0963-0252/25/3/03300231. S. Bathgate,
M. Bilek, and D. McKenzie, " Electrodeless plasma thrusters for
spacecraft: A review," Plasma Sci. Technol. 19, 083001 (2017). https:
//doi.org/10.1088/2058-6272/aa71fe32. D. R. Lev, I. G. Mikellides, D.
Pedrini, D. M. Goebel, B. A. Jorns, and M. S. McDonald, " Recent
Progress in Research and Development of Hollow Cathodes for Electric
Propulsion," Rev. Mod. Plasma Phys. 3, 6 (2019). https://doi.org/
10.1007/s41614-019-0026-033. D. Kahnfeld, J. Duras, P. Matthias, S.
Kemnitz, P. Arlinghaus, G. Bandelow, K. Matyash, N. Koch, and R.
Schneider, " Numerical modeling of high efficiency multistage plasma
thrusters for space applications," Rev. Mod. Plasma Phys. 3, 11
(2019). https://doi.org/10.1007/s41614-019-0030-434. O. Baranov, I.
Levchenko, S. Xu, X. G. Wang, H. P. Zhou, and K. Bazaka, " Direct
current arc plasma thrusters for space applications: Basic physics,
design and perspectives," Rev. Mod. Plasma Phys. 3, 7 (2019). https:/
/doi.org/10.1007/s41614-019-0023-335. Z. Zhang, W. Y. L. Ling, H.
Tang, J. Cao, X. Liu, and N. Wang, " A review of the characterization
and optimization of ablative pulsed plasma thrusters," Rev. Mod.
Plasma Phys. 3, 5 (2019). https://doi.org/10.1007/s41614-019-0027-z
36. K. Takahashi, " Helicon-type radiofrequency plasma thrusters and
magnetic plasma nozzles," Rev. Mod. Plasma Phys. 3, 3 (2019). https:/
/doi.org/10.1007/s41614-019-0024-2 Figure 4 shows the two very
important classes of electrostatic systems, i.e., the Hall-type and
gridded ion thrusters that use a DC potential to accelerate ions.
These systems are currently considered among the most promising
thrust platforms for the long-term missions and for space exploration
within the Solar system and beyond its bounds. In addition to the
thrusters themselves, "plasma cathodes" could be considered as a
separate type of auxiliary but extremely important devices that are
either used in conjunction with electrostatic thrusters or themselves
could be utilized as ultrasmall thrusters. Electrostatic thrusters
always incorporate a set of at least two (sometimes more) electrodes
to create an accelerating DC electric field; the electrostatic
thrusters may also include several electrodes to create a discharge
between them or may be realized in the electrode-less configuration.
An analysis of the current state of art of the electrostatic
thrusters and the advanced techniques for their numerical analysis is
presented below in Sec. II A.
figure
FIG. 3. Characteristic parameters of the major types of space
electric propulsion thrusters in the power-specific impulse
coordinates. The electric propulsion thrust systems span of five
orders of magnitude in power and two orders of magnitude in the
impulse. Such considerable diversity enables the use of this family
of thrusters across very different missions, from the smallest
Cubesat systems to large, powerful spacecraft designed for, e.g.,
manned flights to Mars. Insets illustrate the principal schematics of
each device type.

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figure
FIG. 4. Electrostatic systems: Hall (left) and gridded ion (right)
thrusters, the two major candidates for powering future spacecraft.

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There are a number of electrodynamic space thruster configurations
that are currently being developed (Fig. 5). A typical system of this
type operates by first ionizing the propellant and then accelerating
the ionized species along the channel. A power energy source on board
of a spacecraft is used to generate the electric and magnetic fields
used for generation, control of movement, and acceleration of changes
particles. Once ionized, the particles can be moved along the
acceleration channel by the Lorentz force and expelled out. This
force is the result of the current of the flowing plasma interacting
with the externally applied magnetic field; the magnetic field may
also be induced by the plasma's current. Notable examples of such
devices include the actively researched helicon plasma thruster [HPT,
Fig. 5(a)], magnetoplasmadynamic (MPD) thruster [Fig. 5(b)], and
pulsing thruster [Fig. 5(c)]. Other examples include the Helicon
Electrodeless Advanced Thruster (HEAT), which uses helicon plasma
with high density; the plasma is produced using an RF antenna, with
rotating magnetic field (RMF) coils operated in the open magnetic
field configuration of the divergent field; these are used for the
acceleration of plasma. The rotating magnetic field induces an
azimuthal current j th, and the externally applied static radial
magnetic field B r results in the generation of an axial Lorentz
force f z. If successfully realized, the HEAT-type thrusters will be
the next step in propulsion technology. At present, however, the
prototype devices typically suffer from low efficiency and require
further exploration and optimization.^37,3837. S. Shinohara, " 
Helicon high-density plasma sources: Physics and applications," Adv.
Phys. X 3, 1420424 (2018). https://doi.org/10.1080/
23746149.2017.142042438. S. Shinohara, H. Nishida, T. Tanikawa, T.
Hada, I. Funaki, and K. P. Shamrai, " Development of electrodeless
plasma thrusters with high-density helicon plasma sources," IEEE
Trans. Plasma Sci. 42, 1245-1254 (2014). https://doi.org/10.1109/
TPS.2014.2313633 More details about the characteristics of these
devices are presented in Sec. II B.
figure
FIG. 5. Electrodynamic space thruster systems. (a) Schematic diagram
of the Helicon Electrodeless Advanced Thruster (HEAT). Adapted from
Ref. 3131. S. Bathgate, M. Bilek, and D. McKenzie, " Electrodeless
plasma thrusters for spacecraft: A review," Plasma Sci. Technol. 19,
083001 (2017). https://doi.org/10.1088/2058-6272/aa71fe. (b)
Magnetoplasmadynamic (MPD) thruster. (c) Pulsed plasma thruster. (d)
Conceptual Rotamak-type design of a space thruster. (b) and (d)
Adapted with permission from Appl. Phys. Rev. 5, 011104 (2018).
Copyright 2018 AIP Publishing.^88. I. Levchenko, K. Bazaka, Y. Ding,
Y. Raitses, S. Mazouffre, T. Henning, P. J. Klar, S. Shinohara, J.
Schein, L. Garrigues, M. Kim, D. Lev, F. Taccogna, R. W. Boswell, C.
Charles, H. Koizumi, S. Yan, C. Scharlemann, M. Keidar, and S. Xu, " 
Space micropropulsion systems for Cubesats and small satellites: From
proximate targets to furthermost Frontiers," Appl. Phys. Rev. 5,
011104 (2018). https://doi.org/10.1063/1.5007734

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A. Electrostatic systems: Challenges and opportunities
1. Hall thrusters and variants
Electrostatic thrusters used for space propulsion of satellites and
interplanetary spacecraft include two major types, namely, Hall
thrusters and gridded ion engines as shown in Fig. 4. Ion engines
deliver a high exhaust velocity, but the thrust is limited due to
space charge effects. Hall thrusters offer a larger thrust-to-power
ratio with specific impulses above 1000 s.^18,3918. S. Mazouffre, " 
Electric propulsion for satellites and spacecraft: Established
technologies and novel approaches," Plasma Sources Sci. Technol. 25,
033002 (2016). https://doi.org/10.1088/0963-0252/25/3/03300239. D. M.
Goebel and I. Katz, Fundamentals of Electric Propulsion: Ion and Hall
Thrusters ( John Wiley & Sons, NJ, USA, 2008). In Hall thrusters, a
DC plasma discharge is created inside an opened annular dielectric
cavity, termed the channel, between an anode placed at the back of
the channel and an external cathode. Magnetizing coils or permanent
magnets wrapped around the channel produce a transverse magnetic
field that confines the electrons without altering ion trajectories.
The cathode generates energetic electrons needed both for maintaining
the discharge and for plume neutralization. The propellant gas,
typically xenon for the present generation of Hall thrusters, is
supplied to the channel through either a perforated anode, as
illustrated in Fig. 4, or a dedicated injection system decoupled from
the anode. The cathode-to-anode potential drop is abrupt and located
near the channel exit plane, a region where the electron transport
across the magnetic field is low due to the high magnitude of the
magnetic field.^4040. C. Boniface, L. Garrigues, G. J. M. Hagelaar,
and J. P. Boeuf, " Anomalous cross field electron transport in a Hall
effect thruster," Appl. Phys. Lett. 89, 161503 (2006). https://
doi.org/10.1063/1.2360182 The axial electric field combines with the
radial magnetic field to generate a closed electron drift in the
azimuthal direction, the so-called Hall current, which efficiently
ionizes the propellant gas. Ions are subsequently accelerated outside
the channel by the static electric field. Hall thrusters are thus
essentially electrostatic ion accelerators.^1818. S. Mazouffre, " 
Electric propulsion for satellites and spacecraft: Established
technologies and novel approaches," Plasma Sources Sci. Technol. 25,
033002 (2016). https://doi.org/10.1088/0963-0252/25/3/033002 Hall
thrusters have been designed to operate across a very broad range of
input power from 10 W up to 100 kW using xenon and krypton as
propellant.^4141. Ion thruster prototype breaks records in tests,
could send humans to Mars in just 40 days. Physics and Astronomy
Zone, October 2018. Current state-of-the-art thrusters generate a
thrust level between 1 mN and 5 N, while the specific impulse remains
between 1000 s and 2500 s, which is well above the maximum value that
chemical engines offer.^4242. Ion Thruster Sets World Record. NASA,
updated August 2017. Figure 6 shows an example of a recently
developed low-power Hall thruster suited for microsatellite
maneuvers.^4343. S. Mazouffre and L. Grimaud, " Characteristics and
performances of a 100-W Hall thruster for microspacecraft," IEEE
Trans. Plasma Sci. 46, 330-337 (2018). https://doi.org/10.1109/
TPS.2017.2786402 This thruster produces 8 mN at 150 W with an anode
efficiency above 30%. Figure 7 shows the evolution of the thrust and
the specific impulse with the input power for small Hall thrusters.
The general trend is the decrease in the performance metrics when the
power, i.e., the size and storage capacity of the on-board power
system, decreases. The anode efficiency follows the same tendency.
This fact brings to light the difficulty in developing efficient
miniature Hall thrusters.
figure
FIG. 6. A 100 W class permanent magnet Hall thruster ISCT100
developed in Orleans, France. (a) Photograph of the ISCT100 firing
with xenon at a 100 W input power in the vacuum chamber. A well
collimated plasma jet is observed. (b) Discharge current vs applied
voltage plot. A low level of oscillation is achieved as shaded areas
cover 90% of the discharge current oscillations. Reprinted with
permission from S. Mazouffre and L. Grimaud, IEEE Trans. Plasma Sci.
46, 330-337 (2018). Copyright 2018 IEEE.^4343. S. Mazouffre and L.
Grimaud, " Characteristics and performances of a 100-W Hall thruster
for microspacecraft," IEEE Trans. Plasma Sci. 46, 330-337 (2018).
https://doi.org/10.1109/TPS.2017.2786402

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figure
FIG. 7. Thrust and specific impulse against input power for several
small Hall thrusters. The thrust, I[sp], and anode efficiency
decrease when the power decreases.^6262. L. Grimaud and S. Mazouffre,
" Performance comparison between standard and magnetically shielded
200W Hall thrusters with BN-SiO2 and graphite channel walls," Vacuum
155, 514-523 (2018). https://doi.org/10.1016/j.vacuum.2018.06.056 The
thrust-to-power ratio, however, remains relatively constant at around
65 mN/kW. Reprinted with permision from Mazouffre et al., Proceedings
of the 8th European Conference for Aeronautics and Space Sciences,
Madrid, Spain, July 2019, Paper 214. Copyright 2019 Author(s),
licensed under a Creative Commons Attribution 4.0 License.^6363. S.
Mazouffre, T. Hallouin, M. Inchingolo, A. Gurciullo, P. Lascombes,
and J.-L. Maria, " Characterization of miniature Hall thruster plume
in the 50 - 200 W power range," Proceedings of the 8th European
Conference for Aeronautics and Space Sciences, Madrid, Spain, July
2019, Paper No. 214.

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* "Hall thrusters demonstrate high thrust-to-power ratios and high
  efficiencies over a broad power range, which make them very good
  candidates for various applications that encompass small and
  large satellites as well as Earth orbit missions and
  interplanetary missions. For example, Hall thrusters are the
  prime candidates for the upcoming Mars colonization missions, as
  reported recently by NASA."^41,4241. Ion thruster prototype
  breaks records in tests, could send humans to Mars in just 40
  days. Physics and Astronomy Zone, October 2018.42. Ion Thruster
  Sets World Record. NASA, updated August 2017.

At present, many groups are actively working to improve the
performance and expand the capabilities of Hall thrusters. In
addition to increasing the overall efficiency and the thrust level,
many studies also focus on extending the lifetime, widening the
operational envelope, developing devices with dual-mode (high vs low
specific impulse) functioning, and system simplification.
The development of the Hall thruster configuration known as "magnetic
shielding" has resulted in a drastic improvement in the thruster
lifetime range by decreasing the radial ion kinetic energy in the
acceleration region.^18,44-4818. S. Mazouffre, " Electric propulsion
for satellites and spacecraft: Established technologies and novel
approaches," Plasma Sources Sci. Technol. 25, 033002 (2016). https://
doi.org/10.1088/0963-0252/25/3/03300244. R. R. Hofer, D. M. Goebel,
I. G. Mikellides, and I. Katz, J. Appl. Phys. 115, 043304 (2014).
https://doi.org/10.1063/1.486231445. R. W. Conversano, D. M. Goebel,
R. R. Hofer, I. G. Mikellides, and R. E. Wirz, J. Propul. Power 33,
992-1001 (2017). https://doi.org/10.2514/1.B3623146. L. Grimaud and
S. Mazouffre, " Ion behavior in low-power magnetically shielded and
unshielded Hall thrusters," Plasma Sources Sci. Technol. 26, 055020
(2017). https://doi.org/10.1088/1361-6595/aa660d47. I. G. Mikellides,
I. Katz, R. R. Hofer, and D. M. Goebel, J. Appl. Phys. 115, 043303
(2014). https://doi.org/10.1063/1.486231348. I. G. Mikellides, R. R.
Hofer, I. Katz, and D. M. Goebel, J. Appl. Phys. 116, 053302 (2014).
https://doi.org/10.1063/1.4892160 Gains in the operational lifetime
have been reported across a very broad range of power, with a slight
decrease in efficiency at very low power. In addition, magnetically
shielded thrusters can operate with conducting walls,^49-5149. D. M.
Goebel, R. R. Hofer, I. G. Mikellides, I. Katz, J. E. Polk, and B. N.
Dotson, IEEE Trans. Plasma Sci. 43, 118-126 (2015). https://doi.org/
10.1109/TPS.2014.232111050. Y. Ding et al., Jpn. J. Appl. Phys. 56,
050312 (2017). https://doi.org/10.7567/JJAP.56.05031251. D. Yongjie 
et al., IEEE Trans. Plasma Sci. 46, 263-282 (2018). https://doi.org/
10.1109/TPS.2017.2776257 which provides a pathway to develop new
architectures and explore new application possibilities. The
wall-less configuration has the potential to provide a means for
reducing the wear of the Hall thruster assembly along with proposing
a simplified design, which can be manufactured at a reduced cost.^
52-5652. J. Vaudolon, S. Mazouffre, C. Henaux, D. Harribey, and A.
Rossi, Appl. Phys. Lett. 107, 174103 (2015). https://doi.org/10.1063/
1.493219653. S. Mazouffre, S. Tsikata, and J. Vaudolon, J. Appl.
Phys. 116, 243302 (2014). https://doi.org/10.1063/1.490496554. S.
Mazouffre, L. Grimaud, S. Tsikata, K. Matyash, and R. Schneider,
Plasma Sources Sci. Technol. 28, 054002 (2019). https://doi.org/
10.1088/1361-6595/ab07fc55. Y. Ding, L. Wang, H. Fan, H. Li, W. Xu,
L. Wei, P. Li, and D. Yu, " Simulation research on magnetic pole
erosion of Hall thrusters," Phys. Plasmas 26, 023520 (2019). https://
doi.org/10.1063/1.507704156. Y. Ding et al., Eur. Phys. J. Spec. Top.
226, 2945-2953 (2017). https://doi.org/10.1140/epjst/e2016-60247-y
Sophisticated magnetic field topologies and multistage configurations
are among the possible approaches that are currently considered for
the next generation of devices, see Fig. 8.^57-6157. L. Garrigues, S.
Santhosh, L. Grimaud, and S. Mazouffre, " Operation of a low-power
Hall thruster: Comparison between magnetically unshielded and
shielded configuration," Plasma Sources Sci. Technol. 28, 034003
(2019). https://doi.org/10.1088/1361-6595/ab080d58. A. Shabshelowits,
A. D. Gallimore, and P. Y. Peterson, " Performance of a helicon Hall
thruster operating with xenon, argon, and nitrogen," AIAA Paper
2012-4336, 2012.59. A. I. Bugrova, G. E. Bugrov, V. K. Kharchenikov,
M. I. Shaposhnikov, and S. Mazouffre, Tech. Phys. Lett. 38, 344
(2012). https://doi.org/10.1134/S106378501204002560. S. E. Cusson, M.
P. Georgin, H. C. Dragnea, E. T. Dale, V. Dhaliwal, I. D. Boyd, and
A. D. Gallimore, J. Appl. Phys. 123, 133303 (2018). https://doi.org/
10.1063/1.502827161. S. J. Hall, R. E. Florenz, A. D. Gallimore, H.
Kamhawi, D. L. Brown, J. E. Polk, D. M. Goebel, and R. R. Hofer, AIAA
Paper 2014-3815, 2014. A two-stage Hall thruster with a helicon
preionization stage has been proposed to enhance the ionization
degree of plasma, therefore allowing device operation at high
discharge voltages. To achieve this, the helicon stage is placed
behind the channel, as shown in Fig. 8(a). Although the addition of
radio frequency power allowed us to slightly increase the thrust, the
global efficiency and the thrust-to-power of the device drastically
decreased.^5858. A. Shabshelowits, A. D. Gallimore, and P. Y.
Peterson, " Performance of a helicon Hall thruster operating with
xenon, argon, and nitrogen," AIAA Paper 2012-4336, 2012. Similar
results were obtained with a RF antenna wrapped around a Hall
thruster channel.^5959. A. I. Bugrova, G. E. Bugrov, V. K.
Kharchenikov, M. I. Shaposhnikov, and S. Mazouffre, Tech. Phys. Lett.
38, 344 (2012). https://doi.org/10.1134/S1063785012040025 A Hall
thruster with two magnetic field peaks inside the channel and an
intermediate electrode (IE) placed in the region of low field
magnitude is another possible design. The so-called double stage Hall
thruster, see Fig. 8(b), allows us to better separate the ionization
and acceleration regions, which is necessary to enable dual-mode
operation.^64,6564. J. Perez-Luna, G. J. M. Hagelaar, L. Garrigues,
and J. P. Boeuf, " Model analysis of a double-stage Hall effect
thruster with double-peaked magnetic field and intermediate electrode
," Phys. Plasmas 14, 113502 (2007). https://doi.org/10.1063/1.2783989
65. Y. Ding, P. Li, H. Sun, L. Wei, Y. Xu, W. Peng, H. Su, H. Li, and
D. Yu, " Simulation of double stage hall thruster with double-peaked
magnetic field," Eur. Phys. J. D 71, 192 (2017). https://doi.org/
10.1140/epjd/e2017-80124-8 A similar technique has been proposed
recently with permanent magnets and an electrode located in a zero
field zone near the exit plane, see Fig. 8(c). The two-peak approach
has not demonstrated a large increase in the operation envelope,^64
64. J. Perez-Luna, G. J. M. Hagelaar, L. Garrigues, and J. P. Boeuf,
" Model analysis of a double-stage Hall effect thruster with
double-peaked magnetic field and intermediate electrode," Phys.
Plasmas 14, 113502 (2007). https://doi.org/10.1063/1.2783989 whereas
the system is more complex and heavier than a conventional one. An
innovative design named ID-HALL for the Inductive Double stage HALL
thruster has recently been introduced to efficiently guide ions
produced in the first stage into the acceleration zone.^1111. L.
Dubois, F. Gaboriau, L. Liard, D. Harribey, C. Henaux, L. Garrigues,
G. J. H. Hagelaar, S. Mazouffre, C. Boniface, and J. P. Boeuf, " 
ID-HALL, a new double stage Hall thruster design. I. Principle and
hybrid model of ID-HALL," Phys. Plasmas 25, 093503 (2018). https://
doi.org/10.1063/1.5043354 The ID-HALL architecture is depicted in 
Fig. 8(d). The ionization stage is a RF inductively coupled discharge
of which the antenna is placed inside the inner part of the thruster.
Magnets combined with a specific magnetic circuit create a magnetic
barrier at the channel exit plane, a B-field free region where the
plasma is created and a cusp-like structure is formed to limit the
losses at walls. ID-HALL is optimized to generate ions in the
vicinity of the acceleration region. Preliminary experiments show an
efficient operation of the inductively coupled plasma source with a
large plasma density upstream the channel and extraction of an ion
current when the device operates in a two-stage configuration with a
DC voltage applied between the anode and the external cathode.^1111.
L. Dubois, F. Gaboriau, L. Liard, D. Harribey, C. Henaux, L.
Garrigues, G. J. H. Hagelaar, S. Mazouffre, C. Boniface, and J. P.
Boeuf, " ID-HALL, a new double stage Hall thruster design. I.
Principle and hybrid model of ID-HALL," Phys. Plasmas 25, 093503
(2018). https://doi.org/10.1063/1.5043354
figure
FIG. 8. Examples of strategies currently used to further improve
device architecture and increase performance metrics of Hall
thrusters. Several conceptual designs have been recently proposed.
(a) Double stage Hall thruster with a helicon ionization stage.
Reprinted with permission from Phys. Plasmas 25, 093503 (2018).
Copyright 2018 AIP Publishing.^1111. L. Dubois, F. Gaboriau, L.
Liard, D. Harribey, C. Henaux, L. Garrigues, G. J. H. Hagelaar, S.
Mazouffre, C. Boniface, and J. P. Boeuf, " ID-HALL, a new double
stage Hall thruster design. I. Principle and hybrid model of ID-HALL
," Phys. Plasmas 25, 093503 (2018). https://doi.org/10.1063/1.5043354
(b) Schematic view of the double-stage Hall effect thruster with an
intermediate electrode (IE) and a two magnetic field peak
configuration. Reprinted with permission from Phys. Plasmas 14,
113502 (2007). Copyright 2007 AIP Publishing.^6464. J. Perez-Luna, G.
J. M. Hagelaar, L. Garrigues, and J. P. Boeuf, " Model analysis of a
double-stage Hall effect thruster with double-peaked magnetic field
and intermediate electrode," Phys. Plasmas 14, 113502 (2007). https:/
/doi.org/10.1063/1.2783989 (c) Drawing of a two magnetic peak Hall
thruster using permanent magnets instead of coils. Reprinted with
permission from Ding et al., Eur. Phys. J. D 71, 192 (2017).
Copyright 2017 Springer-Verlag.^6565. Y. Ding, P. Li, H. Sun, L. Wei,
Y. Xu, W. Peng, H. Su, H. Li, and D. Yu, " Simulation of double stage
hall thruster with double-peaked magnetic field," Eur. Phys. J. D 71,
192 (2017). https://doi.org/10.1140/epjd/e2017-80124-8 (d) The
ID-Hall Double-Stage Hall Thruster. The inner cylinder and a RF
antenna used to generate an inductively coupled discharge close to
the acceleration channel. Contour plots represent the magnetic field
intensity distribution (bottom) along with magnetic field lines and
(top) the ideal spatial distribution of the power absorbed per
electron. Reprinted with the permission from Phys. Plasmas 25, 093503
(2018). Copyright 2018 AIP Publishing.^1111. L. Dubois, F. Gaboriau,
L. Liard, D. Harribey, C. Henaux, L. Garrigues, G. J. H. Hagelaar, S.
Mazouffre, C. Boniface, and J. P. Boeuf, " ID-HALL, a new double
stage Hall thruster design. I. Principle and hybrid model of ID-HALL
," Phys. Plasmas 25, 093503 (2018). https://doi.org/10.1063/1.5043354

  * PPT|
  * High-resolution

A promising and effective approach to reach high-power operation and
large thrust generation is the nested-channel Hall thruster.^60,6160.
S. E. Cusson, M. P. Georgin, H. C. Dragnea, E. T. Dale, V. Dhaliwal,
I. D. Boyd, and A. D. Gallimore, J. Appl. Phys. 123, 133303 (2018).
https://doi.org/10.1063/1.502827161. S. J. Hall, R. E. Florenz, A. D.
Gallimore, H. Kamhawi, D. L. Brown, J. E. Polk, D. M. Goebel, and R.
R. Hofer, AIAA Paper 2014-3815, 2014. The principle is to combine
Hall thrusters that vary in sizes and power levels into a
multichannel thruster, as can be seen in Fig. 9. Nesting the
discharge channels lowers the mass and size of this high-power
system. In addition, the nested channel configuration widens the
operating envelope and enables throttling through the selection of
available channels. Thus far, the nested channel technology has been
successfully tested with two and three channels, producing thrusters
capable of operating at over 100 kW of power. Currently, a
two-channel magnetically shielded thruster is under development to
demonstrate that operating life-prolonging technologies can be
successfully applied to high-power devices. This work is of prime
importance as long-life high power Hall thrusters would be a
cost-effective technology for near-Earth and deep space applications.
figure
FIG. 9. A 10 kW class X2 two-channel nested Hall thruster with its
centered-mounted cathode firing with xenon at full power in the dual
channel configuration. Reproduced with the permission from J. Appl.
Phys. 123, 133303 (2018). Copyright 2018 AIP Publishing.^6060. S. E.
Cusson, M. P. Georgin, H. C. Dragnea, E. T. Dale, V. Dhaliwal, I. D.
Boyd, and A. D. Gallimore, J. Appl. Phys. 123, 133303 (2018). https:/
/doi.org/10.1063/1.5028271

  * PPT|
  * High-resolution

2. Ion engines
In ion engines with the electron bombardment ionization, a
cylindrically shaped body houses the discharge unit. The typical unit
consists of a thermionic hollow cathode, an anode, and internally
mounted permanent magnets to confine the discharge plasma. Externally
mounted magnetic coils may be used to confine the plasma in Kaufman
ion thrusters. An acceleration grid unit contains internal and
external grids used for extraction and acceleration, respectively. An
additional cathode is mounted on the outer body of the thruster (
Figs. 3 and 9). The propellant, most often Xe, is delivered to the
hollow cathode, where ionization takes place within a magnetized
discharge. Once it is extracted and accelerated by the respective
grids, the ion flux is expelled from the thruster at a high speed.
The role of the electron flux produced by the externally mounted
cathode is to counteract the electric charging by the ion flux, thus
preventing charge accumulation on the spacecraft. It is worth
mentioning that in both types of thrusters discussed so far, the
plasma is generated and sustained by electron-neutral collisions.
Evidently, plasma can be sustained using other methods, for example,
by using radio frequency- and microwave-driven ionization, with both
methods employed in electric propulsion.
There are many advantages to using gridded ion thrusters, including a
very high specific impulse and high thrust efficiency. Not
surprisingly, the ion thrusters are among the most promising
candidates for automated missions requiring very high fuel
efficiency, such as visiting outer planets and asteroids.^6666. D.
Milligan and D. Gestal, " Flying SMART-1 to the Moon with electric
propulsion," J. British Interplanet. Soc. 61, 466-477 (2008).
However, along with the aforementioned advantages, there are a number
of drawbacks. These include lower ionization efficiencies as compared
to that of Hall thrusters. To overcome this, the radio frequency
ionization stages could be used as an alternative promising
technology to bring the gridded ion thrusters to the orbit of
commercial exploitation. Moreover, the use of iodine instead of the
widely used xenon for gridded ion thrusters may provide a promising
pathway to reduce the cost of the long space flights; however, it is
worth noting that iodine is a corrosive substance and the related
degradation must be considered carefully to ensure sufficiently long
lifetime of this technology for any given mission. The interested
readers may refer to numerous recent publications to review the
current state-of-the-art of various types of the modern gridded ion
thrusters.^67-7267. P. Grondein, T. Lafleur, P. Chabert, and A.
Aanesland, " Global model of an iodine gridded plasma thruster,"
Phys. Plasmas 23, 033514 (2016). https://doi.org/10.1063/1.494488268.
Y. Yamashita, R. Tsukizaki, Y. Yamamoto, D. Koda, K. Nishiyama, and
H. Kuninaka, " Azimuthal ion drift of a gridded ion thruster," Plasma
Sources Sci. Technol. 27, 105006 (2018). https://doi.org/10.1088/
1361-6595/aae29b69. G. Cai, H. Zheng, L. Liu, X. Ren, and B. He, " 
Three-dimensional particle simulation of ion thruster plume
impingement," Acta Astronaut. 151, 645-654 (2018). https://doi.org/
10.1016/j.actaastro.2018.07.00770. Y. Jia, J. Chen, N. Guo, X. Sun,
C. Wu, and T. Zhang, " 2D hybrid-pic simulation of the two and
three-grid system of ion thruster," Plasma Sci. Technol. 20, 105502
(2018). https://doi.org/10.1088/2058-6272/aace5271. H. Zheng, G. Cai,
H. Wang, L. Liu, and B. He, " Three-dimensional particle simulation
of ion thruster plume flows with ex-pws," Plasma Sci. Technol. 20,
105501 (2018). https://doi.org/10.1088/2058-6272/aad5da72. G. Coral,
R. Tsukizaki, K. Nishiyama, and H. Kuninaka, " Microwave power
absorption to high energy electrons in the ECR ion thruster," Plasma
Sources Sci. Technol. 27, 095015 (2018). https://doi.org/10.1088/
1361-6595/aadf04

* Owing to their very high intrinsic specific impulse and other
  advantages, gridded ion thrusters have been historically among
  the most intensely researched space thrust platforms. However,
  the Hall effect thrusters and other emerging thruster concepts
  are currently attracting most of the researchers' attention. The
  use of multistaged radio frequency driven thrusters and
  alternative propellants such as iodine may present the most
  promising directions for further development of efficient
  gridded ion thrusters, particularly for missions that require
  very high specific impulse at low thrust levels.^7373. K.
  Holste, W. Gartner, D. Zschatzsch, S. Scharmann, P. Kohler, P.
  Dietz, and P. Klar, " Performance of an iodine-fueled
  radio-frequency ion-thruster," Eur. Phys. J. D 72, 1-7 (2018).
  https://doi.org/10.1140/epjd/e2017-80498-5

B. Electrodynamic systems
There are a number of benefits to using magnetoplasmadynamic (MPD)
thrusters. These include attractive thrust density approaching 100 mN
cm^-2, high power (approximately megawatt), lower voltage, a simple
device design, and the possibility of using several propellants,
including a variety of gases and metallic solids. This makes this
form of propulsion highly promising for long-distance missions, such
as for deep space exploration, due to a favorable combination of high
efficiency reaching 60% and thrust and impulse reaching tens of
Newtons and 10^4 s, respectively.^74,7574. E. Y. Choueiri, " New dawn
of electric rocket," Sci. Am. 300, 58-65 (2009). https://doi.org/
10.1038/scientificamerican0209-5875. M. R. LaPointe, E.
Strzempkowski, and E. Pencil, " High power MPD thruster performance
measurements," in 40th AIAA/ASME/SAE/ASEE Joint Propulsion Conference
Exhibit (2004). In this device, the interaction between the current
flowing through the plasma and a magnetic field produces the Lorentz
force needed for plasma acceleration. The magnetic field can be
generated using externally mounted coils or arise from the plasma's
own current. It should be noted that there are several concepts of
the MPD systems; e.g., the "applied field molecular dynamics (MD)"
utilizes the externally installed and powered coils to generate a
magnetic field, whereas the "self-field MPD" uses the magnetic field
produced by the discharge current flowing between the main cathode
and anode. Importantly, MPD thrusters demonstrate higher efficiency
in the self-field mode, which features an even simpler design and
power supply system due to the absence of external magnetic coils.
Capable of producing significant (tens of Newton) thrusts at the
megawatt power level, these thrusters are considered among primary
candidates for the future missions related to the Mars and Moon
colonization, where significant cargo masses would need to be
delivered quickly and with the optimal mass-to-cost ratio. They could
be also very promising for missions related to the exploration of
remote planets, i.e., those missions that currently require many
years of flight. However, generating megawatt-level powers in space
would require much more advanced nuclear power systems.^74,7674. E.
Y. Choueiri, " New dawn of electric rocket," Sci. Am. 300, 58-65
(2009). https://doi.org/10.1038/scientificamerican0209-5876. Glenn
Research Center Webpage. Magnetoplasmadynamic thrusters; accessed
August 2019.
Unlike pulsed plasma thrusters (PPTs) that are able to generate the
high specific impulse at low power, MPD thrusters are not ideal for
use in small satellites. Indeed, the former are well suited for
attitude and orientation control, and low-thrust maneuvers by small
space assets. PPTs that use ablation of solid propellants have the
added benefit of design simplicity and high specific impulse.^77,78
77. Z. Wu, G. Sun, S. Yuan, T. Huang, X. Liu, K. Xie, and N. Wang, " 
Discharge reliability in ablative pulsed plasma thrusters," Acta
Astronaut. 137, 8-14 (2017). https://doi.org/10.1016/
j.actaastro.2017.04.00678. T. Schonherr, K. Komurasaki, and G.
Herdrich, " Propellant utilization efficiency in a pulsed plasma
thruster," J. Propul. Power 29, 1478-1487 (2013). https://doi.org/
10.2514/1.B34789 These devices take advantage of the inherent
properties of plasmas to generate thrust and gain considerably high
velocity with very low fuel consumption.^7979. D. Rafalskyi and A.
Aanesland, " Brief review on plasma propulsion with neutralizer-free
systems," Plasma Sources Sci. Technol. 25, 043001 (2016). https://
doi.org/10.1088/0963-0252/25/4/043001
1. Helicon plasma thrusters
Helicon plasma thrusters have emerged as one of the most promising
systems that are currently undergoing active exploration. Helicon
plasma sources (Fig. 10) generate plasmas by using radio frequency
radiation. They generate plasmas of high density (~10^13 cm^-3) and
can sustain a wide range of external operating parameters. For this
reason, many different helicon sources of different geometrical
scales have been designed and their ability to control plasmas
described.^80-8280. S. Shinohara, D. Kuwahara, T. Furukawa, S.
Nishimura, T. Yamase, Y. Ishigami, H. Horita, A. Igarashi, and S.
Nishimoto, " Development of featured high-density helicon sources and
their application to electrodeless plasma thruster," Plasma Phys.
Controlled Fusion 61, 014017 (2019). https://doi.org/10.1088/
1361-6587/aadd6781. D. Kuwahara, S. Shinohara, T. Ishii, S. Otsuka,
T. Nakagawa, K. Kishi, M. Sakata, E. Tanaka, H. Iwaya, K. Takizawa,
Y. Tanida, T. Naito, and K. Yano, " High-density helicon plasma
thrusters using electrodeless acceleration schemes," Trans. JSASS
Aerosp. Tech. Jpn. 14, Pb_117-Pb_121 (2016). https://doi.org/10.2322/
tastj.14.Pb_11782. S. Shinohara, D. Kuwahara, T. Ishii, H. Iwaya, S.
Nishimura, T. Yamase, D. Arai, and H. Horita, " Development of
high-density radio frequency plasma sources with very small diameter
for propulsion," IEEE Trans. Plasma Sci. 46, 252-262 (2018). https://
doi.org/10.1109/TPS.2017.2776110 As the most types of electric
propulsion thrusters mentioned in this article, helicon plasma
thrusters feature very complex physics^83-8683. S. Isayama, S.
Shinohara, and T. Hada, " Review of helicon high-density plasma:
Production mechanism and plasma/wave characteristics," Plasma Fusion
Res. 13, 1101014 (2018). https://doi.org/10.1585/pfr.13.110101484. N.
Sharma, M. Chakraborty, N. K. Neog, and M. Bandyopadhyay, " Design of
a helicon plasma source for ion-ion plasma production," Fusion Eng.
Des. 117, 30-38 (2017). https://doi.org/10.1016/
j.fusengdes.2017.02.00285. O. Grulke, S. Ullrich, T. Windisch, and T.
Klinger, " Laboratory studies of drift waves: Nonlinear mode
interaction and structure formation in turbulence," Plasma Phys.
Controlled Fusion 49, B247 (2007). https://doi.org/10.1088/0741-3335/
49/12B/S2386. N. Sharma, M. Chakraborty, N. K. Neog, and M.
Bandyopadhyay, " Influence of magnetic filter and magnetic cage in
negative ion production in helicon oxygen plasma," Phys. Plasmas 25,
123503 (2018). https://doi.org/10.1063/1.5050983 but hold great
promise for space thruster applications.^8787. B. Tian, M. Merino,
and E. Ahedo, " Two-dimensional plasma-wave interaction in an helicon
plasma thruster with magnetic nozzle," Plasma Sources Sci. Technol.
27, 114003 (2018). https://doi.org/10.1088/1361-6595/aaec32 Experts
anticipate rapid evolution of high-density helicon plasma sources,
for a number of advantages that they offer when compared to other
sources, particularly with respect to the ease of high-density
plasmas over a wide range of external parameters. Nevertheless, more
research efforts are needed to translate various concepts devised
thus far into practical devices to underpin the development of a wide
range of future innovative technologies across many fields, including
fields of fundamental science.^88-9188. J. Navarro-Cavalle, M.
Wijnen, P. Fajardo, and E. Ahedo, " Experimental characterization of
a 1 kW helicon plasma thruster," Vacuum 149, 69-73 (2018). https://
doi.org/10.1016/j.vacuum.2017.11.03689. D. Ichihara, Y. Nakagawa, A.
Uchigashima, A. Iwakawa, A. Sasoh, and T. Yamazaki, " Power matching
between plasma generation and electrostatic acceleration in helicon
electrostatic thruster," Acta Astronaut. 139, 157-164 (2017). https:/
/doi.org/10.1016/j.actaastro.2017.06.03290. M. Merino and E. Ahedo, "
Contactless steering of a plasma jet with a 3d magnetic nozzle,"
Plasma Sources Sci. Technol. 26, 095001 (2017). https://doi.org/
10.1088/1361-6595/aa806191. L. Chang, X. Hu, L. Gao, W. Chen, X. Wu,
X. Sun, N. Hu, and C. Huang, " Coupling of RF antennas to large
volume helicon plasma," AIP Adv. 8, 045016 (2018). https://doi.org/
10.1063/1.5025510
figure
FIG. 10. Schematics of the radio frequency ion thruster including the
electric interconnection of extraction grids and thermionic
neutralizer. U[s] is the screen grid (1) and U[a] is the acceleration
grid (2) voltage, respectively. The deceleration grid is on ground
potential. Electrons for neutralization are provided by a tungsten
filament (U[f] is the filament heating voltage). Reprinted with
permission from Holeste et al., Eur. Phys. J. D 72, 1-7 (2018).
Copyright 2018 Springer-Verlag.^7373. K. Holste, W. Gartner, D.
Zschatzsch, S. Scharmann, P. Kohler, P. Dietz, and P. Klar, " 
Performance of an iodine-fueled radio-frequency ion-thruster," Eur.
Phys. J. D 72, 1-7 (2018). https://doi.org/10.1140/epjd/e2017-80498-5

  * PPT|
  * High-resolution

2. Gradually expanded Rotamak (GER)-type devices
Before helicon plasma thrusters can take their place in the suite of
widely used propulsion devices, a number of challenges would need to
be resolved. These include the erosion of the dielectric wall of the
plasma-confining tube (notably, half of the total thruster power can
be lost in the form of radial particle transport to the walls^92-94
92. D. F. Berisford, R. D. Bengtson, and L. L. Raja, " Power balance
and wall erosion measurements in a helicon plasma," Phys. Plasmas 17,
033503 (2010). https://doi.org/10.1063/1.330418493. J. Del Valle, J.
A. Castro, N. Arce, E. Chinchilla, E. Echeverria, D. Lezama, C.
Martinez, J. Oguilve, A. Rivera, M. Rodriguez et al., " Measurement
of the dielectric wall erosion in helicon plasma thrusters: An
application to the VASIMR VX-CR experiment," in paper presented at
the 33rd International Electric Propulsion Conference, Washington,
DC, USA, October 6-10 (2013), Paper No. IEPC-2013-188.94. K.
Takahashi, A. Chiba, A. Komuro, and A. Ando, " Axial momentum lost to
a lateral wall of a helicon plasma source," Phys. Rev. Lett. 114,
195001 (2015). https://doi.org/10.1103/PhysRevLett.114.195001),
comparatively low rate of propellant ionization, instability
associated with the use of high-power plasmas, to name but a few.
These challenges hinder the advancement of the currently available
magnetoplasmadynamic thrusters. The development of a spherical plasma
source has provided a pathway for the realization of a "gradually
expanded Rotamak" system (GER, Fig. 11) as a potential candidate for
space propulsion. With further development, the GER-type devices
could enable the production of azimuthal plasma currents, and thus to
accelerate species within the plasma, e.g., electrons, ions, and
neutral species, through an axial body force. Other advantages of
GER-type thrusters are the elimination of preionization stages,
neutralizers, and high voltage grids and electrodes typically
required for the efficient performance of ion and Hall thrusters. Of
most significance is the possibility of scaling operational power
regimes, reducing plasma-wall interaction and oblation. These
features will likely make GERs a thruster of choice for long haul
missions in Low Earth Orbit (LEO), geostationary orbits, and deep
space exploration. Rotamak was originally developed (e.g., by
Flinders University in the 1960s) as a more compact alternative to a
tokamak, since it lacks an inner column^9595. W. N. Hugrass, I. R.
Jones, K. F. McKenna, M. G. R. Phillips, R. G. Storer, and H. Tuczek,
" Compact torus configuration generated by a rotating magnetic field:
The Rotamak," Phys. Rev. Lett. 44, 1676 (1980). https://doi.org/
10.1103/PhysRevLett.44.1676 and uses a spherical discharge vessel.
The external sources are configured to enable a "field reversed
configuration" as well as other current drive schemes.^9696. I. R.
Jones, A. Lietti, and J.-M. Peiry, " A rotating magnetic field pinch
," Plasma Phys. 10, 213 (1968). https://doi.org/10.1088/0032-1028/10/
3/302 A prototype GER propulsion device was recently developed by the
Space and Propulsion Center (SPC) at the National Institute of
Education, Nanyang Technological University, Singapore. Early results
of its use for space propulsion are encouraging, confirming its
potential for the eventual development into a pure electromagnetic
thruster that could sustain high density, noninductive plasmas. A
pair of parallel RF coils can be used to sustain these plasmas, with
the coils located outside of a spherical confinement vessel.
Additional coils are located orthogonally to the former RF coils to
provide a poloidal magnetic field by the DC pulses. The poloidal
field confines and densifies the plasma in the middle of the vessel.
It is possible to modify the device configuration and geometry to
build a fully electromagnetic thruster, with the acceleration and the
thrust sustained by an axial force in the absence of any neutralizes
and grids, typical of conventional electric propulsion platforms.
Larger thrusts per unit of the propellant spent could be generated,
the latter being a requirement for longer-haul missions.
figure
FIG. 11. (a) and (b) Schematics of the helicon plasma systems
operating in the "rotating magnetic field" (RMF) mode, which has been
originally utilized in the nuclear fusion field (a), and in the m = 0
"half-cycle acceleration mode" (here, m is an azimuthal mode number).
The basic mechanism is to induce an azimuthal current j[th] in the
divergent magnetic field to produce the j[th] x B[r] axial Lorentz
force, where B[r] is the static radial magnetic field. Reprinted with
permission from Plasma Phys. Controlled Fusion 61, 014017 (2019).
Copyright 2019 IOP.^8080. S. Shinohara, D. Kuwahara, T. Furukawa, S.
Nishimura, T. Yamase, Y. Ishigami, H. Horita, A. Igarashi, and S.
Nishimoto, " Development of featured high-density helicon sources and
their application to electrodeless plasma thruster," Plasma Phys.
Controlled Fusion 61, 014017 (2019). https://doi.org/10.1088/
1361-6587/aadd67 (c) Helicon plasma thruster firing in the 500-1000 W
radio frequency power range, at 13.56 MHz with xenon in the vacuum
chamber. Importantly, in the helicon thrusters, the plasma flow could
be efficiently controlled.^9090. M. Merino and E. Ahedo, " 
Contactless steering of a plasma jet with a 3d magnetic nozzle,"
Plasma Sources Sci. Technol. 26, 095001 (2017). https://doi.org/
10.1088/1361-6595/aa8061 Reprinted with permission from Vacuum 149,
69 (2018). Copyright 2018 Elsevier.^8888. J. Navarro-Cavalle, M.
Wijnen, P. Fajardo, and E. Ahedo, " Experimental characterization of
a 1 kW helicon plasma thruster," Vacuum 149, 69-73 (2018). https://
doi.org/10.1016/j.vacuum.2017.11.036

  * PPT|
  * High-resolution

3. Arc thrusters
Pulsed and ablative systems are examples of thrust systems that share
similar physical mechanisms and very small size (up to several
millimeters), which makes them well suited for small satellites.^
97-9997. J. Zhang, X. Li, W. Yang, W. Yan, D. Wei, Y. Liu, and G.
Yan, " The effect of the length to diameter ratio on capillary
discharge plasmas," Phys. Plasmas 25, 103501 (2018). https://doi.org/
10.1063/1.504178198. K. F. Luskow, P. R. C. Neumann, G. Bandelow, J.
Duras, D. Kahnfeld, S. Kemnitz, P. Matthias, K. Matyash, and R.
Schneider, " Particle-in-cell simulation of the cathodic arc thruster
," Phys. Plasmas 25, 013508 (2018). https://doi.org/10.1063/1.5012584
99. L. Yang, G. Zeng, H. Tang, Y. Huang, and X. Liu, " Numerical
studies of wall-plasma interactions and ionization phenomena in an
ablative pulsed plasma thruster," Phys. Plasmas 23, 073518 (2016).
https://doi.org/10.1063/1.4959807 "Microcathode arc thrusters"
(m-CAT, Fig. 12) are also actively investigated, with examples
including microthrusters employing a Ring Electrode, a Coaxial
Electrode, and an Alternating Electrode developed by the George
Washington University's Micropropulsion and Nanotechnology Laboratory
(MpNL) since 2009. These configurations differ with respect to their
performance and operational characteristics, namely, thrust and
working life. On average, m-CAT available at present features a
thrust-to-power ratio and efficiency of approximately 20 mN/W and
15%, respectively. A major limitation of this device is that ~10% of
the discharge current contributes to the ion current, and thus to
thrust, with ~90% of the discharge current conducted by electrons
spent on anode heating.^8,100,1018. I. Levchenko, K. Bazaka, Y. Ding,
Y. Raitses, S. Mazouffre, T. Henning, P. J. Klar, S. Shinohara, J.
Schein, L. Garrigues, M. Kim, D. Lev, F. Taccogna, R. W. Boswell, C.
Charles, H. Koizumi, S. Yan, C. Scharlemann, M. Keidar, and S. Xu, " 
Space micropropulsion systems for Cubesats and small satellites: From
proximate targets to furthermost Frontiers," Appl. Phys. Rev. 5,
011104 (2018). https://doi.org/10.1063/1.5007734100. D. B.
Zolotukhin, S. Hurley, and M. Keidar, " Anode ablation and
performance improvement of microcathode arc thruster," Plasma Sources
Sci. Technol. 28, 034001 (2019). https://doi.org/10.1088/1361-6595/
ab01ec101. D. B. Zolotukhin and M. Keidar, " Optimization of
discharge triggering in micro-cathode vacuum arc thruster for
CubeSats," Plasma Sources Sci. Technol. 27, 074001 (2018). https://
doi.org/10.1088/1361-6595/aacdb0
figure
FIG. 12. (a) Lab prototype of the Rotamak system, now under
exploration as a novel elctric propulsion system at the Space and
Propulsion Center (SPC) at the National Institute of Education,
Nanyang Technological University, Singapore. (b) Schematics of the
proposed concept of the microcathode arc thruster with high thrust
(m-CAT-HT). Such a thruster can feature a thrust-to-power ratio of
about 20 mN/W, with the efficiency of up to 15%. Plasma is also
accelerated by the Lorentz forces. Reprinted with permission
Levchenko et al., Appl. Phys. Rev. 5, 011104 (2018). Copyright 2018
Author(s), licensed under a Creative Commons Attribution (CC BY)
license.^88. I. Levchenko, K. Bazaka, Y. Ding, Y. Raitses, S.
Mazouffre, T. Henning, P. J. Klar, S. Shinohara, J. Schein, L.
Garrigues, M. Kim, D. Lev, F. Taccogna, R. W. Boswell, C. Charles, H.
Koizumi, S. Yan, C. Scharlemann, M. Keidar, and S. Xu, " Space
micropropulsion systems for Cubesats and small satellites: From
proximate targets to furthermost Frontiers," Appl. Phys. Rev. 5,
011104 (2018). https://doi.org/10.1063/1.5007734

  * PPT|
  * High-resolution

Overall, at the present stage of development and understanding of the
basic plasma physic mechanisms of the electrodynamic space thrusters,
we can see the following opportunities and advantages presented by
electrodynamic plasma thrusters when compared to electrostatic and
electrothermal propulsion devices:

* ability to produce considerable thrust densities, since particle
  acceleration is not restricted by the positive space charge in
  the acceleration channel or by grid electrical screening;
* absence of the requirement for a neutralizer since the
  ponderomotive force is capable of accelerating all plasma
  species along the direction of the plume;
* ability to switch the thruster between optimum specific impulse
  and greater thrust while maintaining constant power enabled by
  the inherent multistaged nature of the electrodeless plasma
  thruster, which allows for independent optimization;
* minimal electrode degradation and absence of plasma
  contamination for the helicon and Rotamak devices enabled by the
  use of a combination of nonuniform high frequency field and a
  static magnetic field to generate the ponderomotive force, which
  means that the plasma does not come into direct contact with
  electrodes and no grids are used for species acceleration and
  extraction.

C. Hollow cathode systems for space electric propulsion thrusters
Hollow cathodes are used in the Hall effect and ion thrusters to
provide electrons for the propellant ionization and the
neutralization of the ion beam. The cathode affects the overall
performance and lifetime of the thruster unit. The cathode propellant
consumption, along with a possible additional power required to
ensure its operation, has a direct impact on the thrust efficiency.
The cathode position is an important aspect to be studied, since it
affects the thruster performance characteristics and the cathode
erosion. As such, important goals for the cathode development include
the reduction of propellant consumption, improvement of the thermal
design to lower the heat losses from the hot parts, and the increase
in the cathode service life. Below, we will briefly discuss the
recent advances and current trends in the development of hollow
cathodes, starting from an outline of the basic physical phenomena
involved in the operation of hollow plasma cathodes. We will then
discuss some of the achievements in the modeling and simulation of
plasma cathodes and describe the design and performance of low and
high current hollow cathodes, respectively.
1. Physical phenomena in cathodes
The general schematic of a traditional hollow cathode is shown in 
Fig. 13.^3939. D. M. Goebel and I. Katz, Fundamentals of Electric
Propulsion: Ion and Hall Thrusters ( John Wiley & Sons, NJ, USA,
2008). The cathode uses a refractory metal tube to support the
thermionic insert (or emitter). The insert is kept in its position by
a pusher and spring arrangement and is pushed against a refractory
metal end plate with a chamfered orifice. Historically, two types of
inserts have been used in hollow cathodes: barium-oxide impregnated
tungsten dispenser inserts and lanthanum hexaboride (LaB[6]).^102102.
D. M. Goebel, R. M. Watkins, and K. Jameson, " LaB6 Hollow Cathodes
for Ion and Hall Thrusters," J. Prop. Powe 23, 527-528 (2007). https:
//doi.org/10.2514/1.25475 Barium-oxide inserts have a low work
function (about 2.1 eV), but a maximum continuous current density of
20 A/cm^2 at a temperature of about 1200 degC. The LaB[6] insert is a
well-known thermionic insert that has been used in low power flight
Hall thrusters built in the Soviet Union and later in the Russian
Federation since the 1970s.^103103. B. A. Arkhipov and K. N.
Kozubsky, " The development of the cathode compensators for
stationary plasma thrusters in the USSR," in 22nd International
Electric Propulsion Conference, Viareggio, Italy, October 14-17
(1991), Paper No. IEPC-91-023. LaB[6] inserts have a higher work
function (2.67 eV) when compared to BaO dispenser cathodes and
therefore operate at a temperature just exceeding 1600 degC to generate
approximately 10 A/cm^2 emission current density. LaB[6] also has low
evaporation rates and is insensitive to poisoning from the impurities
in the propellant gas.
figure
FIG. 13. A typical configuration of a hollow cathode showing its main
components.^3939. D. M. Goebel and I. Katz, Fundamentals of Electric
Propulsion: Ion and Hall Thrusters ( John Wiley & Sons, NJ, USA,
2008). The insets made of a material with a low work function ensures
an efficient emission of electrons. A heater is used to maintain the
high temperature needed for electron emission and also reduces the
total heat flux from an outer surface of the cathode (an additional
thermal screen can also be used to further enhance the device
efficiency). Reprinted with permission from Levchenko et al., Nat.
Commun. 9, 879 (2018). Copyright 2018 Author(s), licensed under a
Creative Commons Attribution 4.0 License.^139139. I. Levchenko, S.
Xu, G. Teel, D. Mariotti, M. L. R. Walker, and M. Keidar, " Recent
progress and perspectives of space electric propulsion systems based
on smart nanomaterials," Nat. Commun. 9, 879 (2018). https://doi.org/
10.1038/s41467-017-02269-7

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  * High-resolution

A heater can be included in the cathode assembly to warm the insert
up to the thermionic emission temperatures prior to ignition. High
current cathodes feature a high temperature coaxial sheathed heater,
which is wound around the cathode to deliver sufficient heating to
start the discharge. Alternative heater solutions in use or under
development are described in the recently published comprehensive
reviews on the cathodes for electric propulsion systems.^3232. D. R.
Lev, I. G. Mikellides, D. Pedrini, D. M. Goebel, B. A. Jorns, and M.
S. McDonald, " Recent Progress in Research and Development of Hollow
Cathodes for Electric Propulsion," Rev. Mod. Plasma Phys. 3, 6
(2019). https://doi.org/10.1007/s41614-019-0026-0 A heat shield
comprising layers of thin refractory metal foil encases the heater
coil to provide for greater heating efficiency. This arrangement is
surrounded by an isolated "keeper" electrode, the purpose of which is
to assist in igniting the discharge and also to provide protection to
the orifice plate against the energetic ion bombardment from the
cathode plume. The selection of material for the keeper electrode is
aimed to minimize sputtering, with graphite keepers often chosen for
present high current cathodes.
In recent years, extensive theoretical research on a variety of
hollow cathode phenomena has been conducted. The research focused
mainly on several specific physical processes: the neutral flow
dynamics in the cathode interior,^104,105104. I. G. Mikellides, I.
Katz, K. Jameson, and D. Goebel, " Driving processes in the orifice
and near-plume regions of a hollow cathode," in 42nd AIAA/ASME/SAE/
ASEE Joint Propulsion Conference & Exhibit (American Institute of
Aeronautics and Astronautics, 2006).105. K. Kubota, Y. Oshio, H.
Watanabe, S. Cho, Y. Ohkawa, and I. Funaki, " Hybrid-PIC Simulation
on Plasma Flow of Hollow Cathode. Trans. Japan Soc. Aeronaut. Space
Sciences," Aerosp. Technol. Jpn. 14, Pb_189-Pb_195 (2016). https://
doi.org/10.2322/tastj.14.Pb_189 electron transport and anomalous
resistivity,^106-111106. I. G. Mikellides, I. Katz, D. M. Goebel, and
K. K. Jameson, " Evidence of nonclassical plasma transport in hollow
cathodes for electric propulsion," J. Appl. Phys. 101, 063301 (2007).
https://doi.org/10.1063/1.2710763107. A. L. Ortega, B. A. Jorns, and
I. G. Mikellides, " Hollow cathode simulations with a
first-principles model of ion-acoustic anomalous resistivity," J.
Propul. Power 1, 13 (2018). https://doi.org/10.2514/1.B36782108. G.
Sary, L. Garrigues, and J. P. Boeuf, " Hollow cathode modeling: I. A
coupled plasma thermal two-dimensional model," Plasma Sources Sci.
Technol. 26, 055007 (2017). https://doi.org/10.1088/1361-6595/aa6217
109. R. Z. Sagdeev and A. Galeev, Nonlinear Plasma Theory ( W. A.
Benjamin, New York, 1969).110. R. C. Davidson and N. A. Krall, " 
Anomalous transport in high-temperature plasmas with applications to
solenoidal fusion systems," Nucl. Fusion 17, 1313-1372 (1977). https:
//doi.org/10.1088/0029-5515/17/6/017111. D. M. Goebel, K. K. Jameson,
I. Katz, and I. G. Mikellides, " Potential fluctuations and energetic
ion production in hollow cathode discharges," Phys. Plasmas 14,
103508 (2007). https://doi.org/10.1063/1.2784460 and spot and plume
mode physics.^112,113112. G. Sary, L. Garrigues, and J. P. Boeuf, " 
Hollow cathode modeling: II. Physical analysis and parametric study,"
Plasma Sources Sci. Technol. 26, 055008 (2017). https://doi.org/
10.1088/1361-6595/aa6210113. M. P. Georgin, B. A. Jorns, and A. D.
Gallimore, " An experimental and theoretical study of hollow cathode
plume mode oscillations," in 35rd International Electric Propulsion
Conference, Atlanta, GA, October (2017), Paper No. IEPC-2017-298.
Particular attention was given to the theoretical and experimental
investigation of cathode instabilities, in both the cathode interior
and cathode plume region.^114-116114. P. Guerrero, I. G. Mikellides,
and J. E. Polk, " Hollow cathode thermal modelling and
self-consistent solutions. Work function evaluation for a LaB[6]
cathode," in 54th AIAA/SAE/ASEE Joint Propulsion Conference, AIAA
Propulsion and Energy Forum: American Institute of Aeronautics and
Astronautics (2018).115. B. A. Jorns, C. Dodson, D. A. Goebel, and R.
Wirz, " Propagation of ion acoustic wave energy in the plume of a
high-current LaB6 hollow cathode," Phys. Rev. E 96, 023208 (2017).
https://doi.org/10.1103/PhysRevE.96.023208116. T. Matlock, D. A.
Goebel, R. Conversano, and R. Wirz, " An investigation of low
frequency plasma instabilities in a cylindrical hollow cathode
discharge," in AIAA Paper 2014-3508, 2014. The ultimate goal of the
aforementioned studies was to broaden the understanding of
cathode-related physics, as well as to formulate relationships
between the various cathode parameters. These relationships would
enable the design of more power- and propellant-efficient cathodes.
Confronting the aforementioned theoretical challenges would advance
the cathode effectiveness in the near future and provide researchers
with the ability to adequately design and test hollow cathodes.
First, deeper understanding of cathode plume physics would enable
proper testing of cathodes in diode mode configurations (against an
anode structure instead of with a thruster). Further understanding of
the cathode plume physics can dictate the required experimental
setup, i.e., anode geometry, cathode-anode distance, additional
peripheral mass flow rate, background pressure, etc.
Second, an improved theoretical understanding of the cathode/keeper
orifice physics would lead to possible mitigation of orifice wear
that would potentially extend cathode life and enable operation at a
wide range of discharge currents, specifically high current levels.
Third, theoretical understanding of the interaction between the
plasma flow and the interior cathode structure would allow for the
development of novel cathode configurations. For example, the physics
of "open-end emitter, orificed keeper" configurations, commonly used
in heaterless hollow cathodes (HHCs), would reveal the optimal
geometry for the efficient emitter heating while minimizing ion
density and energy in the vicinity of the keeper orifice, thus
reducing orifice erosion.
Finally, it is natural that further theoretical research of
cathode-related physics would unfold a myriad of new possibilities,
currently unconceived, ultimately leading to new and improved cathode
configurations, designs, and cathode operation schemes.
2. Low current hollow cathodes
The low current cathodes find their principal use in nano- and
microsatellites deployed for varied purposes: scientific research,
Earth observation, astronomy, as well as technological, educational,
and military applications. As previously noted, advances in
microelectronics and miniaturized systems provided the practical
means to lower the operating power of electric thrusters, with the
goal of addressing the micro/mini propulsion market.^88. I.
Levchenko, K. Bazaka, Y. Ding, Y. Raitses, S. Mazouffre, T. Henning,
P. J. Klar, S. Shinohara, J. Schein, L. Garrigues, M. Kim, D. Lev, F.
Taccogna, R. W. Boswell, C. Charles, H. Koizumi, S. Yan, C.
Scharlemann, M. Keidar, and S. Xu, " Space micropropulsion systems
for Cubesats and small satellites: From proximate targets to
furthermost Frontiers," Appl. Phys. Rev. 5, 011104 (2018). https://
doi.org/10.1063/1.5007734 The related activities aim at the
development of propulsion subsystems characterized by low cost, low
power consumption, low mass, high thrust controllability, and
manufacturing capability. The latter aspect is particularly important
for constellations of satellites, which will mainly use electric
propulsion for end-of-life de-orbiting. Another aspect under
continuous investigation is the possibility to operate the electric
thrusters with alternative propellants; in particular, iodine is a
valid candidate to be used in low-power applications.^117117. J. W.
Dankanich and D. M. Schumacher, " Iodine propulsion advantages for
low cost mission applications and the iodine satellite (ISAT)
technology demonstration," in 66th International Astronautical
Congress, Jerusalem, Israel (2015), Paper No. IAC-15-D2.5.7x31069.
The traditional hollow cathode architecture (Fig. 14) based on
lanthanum hexaboride or barium-oxide tungsten impregnated inserts has
been adopted by various research institutions and industries.^118-123
118. A. Parakhin, R. S. Pobbubniy, A. N. Nesterenko, and A. P.
Sinitsin, " Low-current cathode with BaO based thermoemitter," Proc.
Eng. 185, 80-84 (2017). https://doi.org/10.1016/j.proeng.2017.03.295
119. P. Saevets, D. Semenenko, R. Albertoni, and G. Scremin, " 
Development of a long-life low-power Hall thruster," in 35th
International Electric Propulsion Conference, Georgia Institute of
Technology, Atlanta, Georgia, USA October 8-12 (2017), Paper No.
IEPC-2017-38.120. P. M. Puchkov, " The low-current cathode for a
small power electric propulsion,"in 7th European Conference for
Aeronautics and Space Sciences, Milan, Italy, 3-6 July (2017), Paper
No. EUCASS2017-138.121. A. Loyan, M. Titov, O. Rybalov, and T.
Maksymenko, " Middle power Hall effect thrusters with centrally
located cathode," in 33rd International Electric Propulsion
Conference (IEPC), Washington, DC, USA, 6-10 October (2013), Paper
No. IEPC-2013-410.122. D. Pedrini, C. Ducci, T. Misuri, F. Paganucci,
and M. Andrenucci, " Sitael hollow cathodes for low-power Hall effect
thrusters," IEEE Trans. Plasma Sci. 46, 296-303 (2018). https://
doi.org/10.1109/TPS.2017.2778317123. D. Lev and L. Appel, " 
Heaterless hollow cathode technology--A critical review," in 5th Space
Propul. Conf. (SPC), Rome, Italy, 2-6 May (2016), Paper No.
SP2016_3125366. However, other promising insert materials, such as
the electride C12A7e-, are under investigation for the low current
class of hollow cathodes.^124,125124. C. Drobny, J. W. Wulfkuhler, K.
Watzig, and M. Tajmar, " Detailed work function measurements and
development of a hollow cathode using the emitter material C12A7
electride," in Space Propulsion Conf., Seville, Spain, 14-18 May
(2018), Paper No. SP2018_92.125. M. S. McDonald and N. R. S. Caruso,
" Ignition and early operating characteristics of a low-current C12A7
hollow cathode," in 35th International Electric Propulsion Conference
(IEPC), Atlanta, GA, USA, 8-12 October (2017), Paper No.
IEPC-2017-253. The traditional hollow cathode design presents a
single point of failure, namely, the heater. The heater is generally
made of a refractory wire (tantalum or tungsten alloy) and is
electrically insulated from the cathode tube by means of ceramic
components. Alternatively, a potted heater is included in the cathode
assembly. The mineral insulated cables used to heat the high-current
hollow cathodes could also be used for the low current cathodes,
provided the cable dimensions are efficiently scaled down to fit the
smaller geometrical envelope.^3232. D. R. Lev, I. G. Mikellides, D.
Pedrini, D. M. Goebel, B. A. Jorns, and M. S. McDonald, " Recent
Progress in Research and Development of Hollow Cathodes for Electric
Propulsion," Rev. Mod. Plasma Phys. 3, 6 (2019). https://doi.org/
10.1007/s41614-019-0026-0
figure
FIG. 14. (a) SITAEL's HC1 cathode and (b) Rafael's RHHC (Rafael
Heaterless Hollow Cathode) cathode. (c) The X3 cathode assembly with
external gas injectors required for operation over 200 A of discharge
current. (a) and (c) Reprinted with permission from Lev et al., Rev.
Mod. Plasma Phys. 3, 6 (2019). Copyright 2019 Springer-Nature.^3232.
D. R. Lev, I. G. Mikellides, D. Pedrini, D. M. Goebel, B. A. Jorns,
and M. S. McDonald, " Recent Progress in Research and Development of
Hollow Cathodes for Electric Propulsion," Rev. Mod. Plasma Phys. 3, 6
(2019). https://doi.org/10.1007/s41614-019-0026-0 (b) Reprinted with
permission from Lev et al., IEEE Trans. Plasma Sci. 46, 311 (2018).
Copyright 2018 IEEE.^126126. D. R. Lev and G. Alon, " Operation of a
hollow cathode neutralizer for sub-100-W hall and ion thrusters,"
IEEE Trans. Plasma Sci. 46, 311-318 (2018). https://doi.org/10.1109/
TPS.2017.2779409

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  * High-resolution

To overcome the reliability and manufacturing issues related to the
heater, the Heaterless Hollow Cathode (HHC) architecture was devised
that does not require external heating to bring the electron insert
to its operation temperature. Instead of using external heating, as
with conventional cathodes, HHCs are heated via plasma heating. When
the temperature of the electron insert is sufficiently high, the HHC
works in a similar way to any other conventional hollow cathode
operating, under steady state conditions. HHCs are suitable primarily
for low-current hollow cathodes, since the heaterless ignition may
induce a high thermal stress on the insert when reaching relatively
high discharge current levels.^126-128126. D. R. Lev and G. Alon, " 
Operation of a hollow cathode neutralizer for sub-100-W hall and ion
thrusters," IEEE Trans. Plasma Sci. 46, 311-318 (2018). https://
doi.org/10.1109/TPS.2017.2779409127. M. Schatz, " Heaterless ignition
of inert gas ion thruster hollow cathodes," in 18th International
Electric Propulsion Conference (IEPC), Alexandria, VA, USA, 30
September-2 October (1985).128. Z.-X. Ning, H.-G. Zhang, X.-M. Zhu,
L. Ouyang, X.-Y. Liu, B.-H. Jiang, and D.-R. Yu, " 
10000-ignition-cycle investigation of a LaB[6] hollow cathode for
3-5-kilowatt Hall thruster," J. Propul. Power 35, 87-93 (2019).
https://doi.org/10.2514/1.B37192
In recent years, the interest in HHCs for low current hollow cathodes
has been growing.^129-134129. V. Vekselman, Y. E. Krasik, S. Gleizer,
V. T. Gurovich, A. Warshavsky, and L. Rabinovich, " Characterization
of a heaterless hollow cathode," J. Propul. Power 29, 475-486 (2013).
https://doi.org/10.2514/1.B34628130. L. P. Rand and J. D. Williams, "
Instant start electride hollow cathode," in 33rd Intnational Electric
Propulsion Conference (IEPC), Washington DC, USA, 6-10 October
(2013), Paper No. IEPC-2013-305.131. F. Nurmberger, A. Hock, and M.
Tajmar, " Design and experimental investigation of a low-power Hall
effect thruster and a low-current hollow cathode," AIAA Paper
2015-3822 (2015).132. A. Daykin-Iliopoulos, S. Gabriel, I. Golosnoy,
K. Kubota, and I. Funaki, " Investigation of heaterless hollow
cathode breakdown," in 34th International Electric Propulsion
Conference (IEPC), Hyogo-Kobe, Japan, 6-9 July (2015), Paper No.
IEPC-2015-193.133. D. Pedrini, T. Misuri, F. Paganucci, and M.
Andrenucci, " Development of hollow cathodes for space electric
propulsion at sitael," Aerospace 4, 26 (2017). https://doi.org/
10.3390/aerospace4020026134. D. Lev, G. Alon, L. Appel, O. Seeman,
and Y. Hadas, " Low current heaterless hollow cathode development
overview," in 35th International Electric Propulsion Conference
(IEPC), Atlanta, GA, USA, 8-12 October (2017), Paper No.
IEPC-2017-244. The quick ignition time, low power demand during the
ignition phase, and the potentially longer lifetime have made these
cathodes an attractive option for low power ion and Hall thrusters.
To date, the HHC technology has overcome two technological
challenges: the ignition voltage has been reduced to merely several
hundred volts^123123. D. Lev and L. Appel, " Heaterless hollow
cathode technology--A critical review," in 5th Space Propul. Conf.
(SPC), Rome, Italy, 2-6 May (2016), Paper No. SP2016_3125366. and the
transition to operational temperature of the insert is with minimal
damage to the cathode, thus allowing for thousands of ignitions.^134
134. D. Lev, G. Alon, L. Appel, O. Seeman, and Y. Hadas, " Low
current heaterless hollow cathode development overview," in 35th
International Electric Propulsion Conference (IEPC), Atlanta, GA,
USA, 8-12 October (2017), Paper No. IEPC-2017-244. Further, it was
shown that low-power HHCs can operate adequately with different
insert materials such as the electride C12A7e-,^130,131130. L. P.
Rand and J. D. Williams, " Instant start electride hollow cathode," 
in 33rd Intnational Electric Propulsion Conference (IEPC), Washington
DC, USA, 6-10 October (2013), Paper No. IEPC-2013-305.131. F.
Nurmberger, A. Hock, and M. Tajmar, " Design and experimental
investigation of a low-power Hall effect thruster and a low-current
hollow cathode," AIAA Paper 2015-3822 (2015). BaO-impregnated
tungsten,^133-135133. D. Pedrini, T. Misuri, F. Paganucci, and M.
Andrenucci, " Development of hollow cathodes for space electric
propulsion at sitael," Aerospace 4, 26 (2017). https://doi.org/
10.3390/aerospace4020026134. D. Lev, G. Alon, L. Appel, O. Seeman,
and Y. Hadas, " Low current heaterless hollow cathode development
overview," in 35th International Electric Propulsion Conference
(IEPC), Atlanta, GA, USA, 8-12 October (2017), Paper No.
IEPC-2017-244.135. J. Li, J. Wei, Y. Feng, and X. Li, " Effect of CaO
on phase composition and properties of aluminates for barium tungsten
cathode," Materials 11, 1380 (2018). https://doi.org/10.3390/
ma11081380 and LaB[6].^132,133132. A. Daykin-Iliopoulos, S. Gabriel,
I. Golosnoy, K. Kubota, and I. Funaki, " Investigation of heaterless
hollow cathode breakdown," in 34th International Electric Propulsion
Conference (IEPC), Hyogo-Kobe, Japan, 6-9 July (2015), Paper No.
IEPC-2015-193.133. D. Pedrini, T. Misuri, F. Paganucci, and M.
Andrenucci, " Development of hollow cathodes for space electric
propulsion at sitael," Aerospace 4, 26 (2017). https://doi.org/
10.3390/aerospace4020026
Nevertheless, the current state of HHC technology development still
needs to overcome two leading challenges:

(1) Cathode conditioning: after the exposure to ambient air,
    the insert must be conditioned, which is gradually heated
    to emit impurities.^136136. T. Verhey and G. Macrae, " 
    Requirements for long-life operation of inert gas hollow
    cathodes--Preliminary results," in 21st International
    Electric Propulsion Conference (1990). However, since HHCs
    are heated using plasma that is formed within the cathode
    cavity, a dedicated rigorous and methodological research is
    needed to identify the appropriate cathode conditioning
    schemes. The research should focus on correlating the
    keeper (or anode) current, insert temperatures, and the
    required time to achieve the cathode conditioning for each
    current level;
(2) The sensitivity of breakdown voltage to temperature: it has
    been demonstrated that in the cylindrical geometry, the
    decrease in the temperature leads to an increase in
    breakdown voltage.^137137. H. S. Uhm, S. J. Jung, and H. S.
    Kim, " Influence of gas temperature on electrical breakdown
    in cylindrical electrodes," J. Korean Phys. Soc. 42, 989-93
    (2003). A device the use of which can lead to the reduction
    of HHC temperatures prior to ignition has been proposed and
    physically realized.^138138. D. Katz-Franco and D. Lev, " 
    Conceptual design of a radiative cooling system for
    heaterless hollow cathodes," in Proceedings 34th
    Internationa Electric Propulsion Conference (IEPC),
    Hyogo-Kobe, Japan, 4-10 July (2015), Paper No.
    IEPC-2015-164. However, the outcomes of the test of the
    sensitivity of cathode ignition to cathode temperature have
    not yet been communicated to the research community. To
    properly qualify an HHC for in-space missions, its
    sensitivity to low temperatures, primarily the required
    ignition voltage, should be studied experimentally.

New frontiers of the low current cathode development are likely to
include new designs, new concepts, and new advanced materials, and
the combination of thereof. For example, ultrananoporous inserts are
under study to reach a longer cathode lifetime, through a larger
surface area per volume unit, also increasing the efficiency due to
the smaller required heated volume.^139139. I. Levchenko, S. Xu, G.
Teel, D. Mariotti, M. L. R. Walker, and M. Keidar, " Recent progress
and perspectives of space electric propulsion systems based on smart
nanomaterials," Nat. Commun. 9, 879 (2018). https://doi.org/10.1038/
s41467-017-02269-7 Carbon nanotubes possess a potential for cold,
propellant-free cathodes, whereas nanoscale metamaterials capable of
reversal heat transmission could help reduce heat losses.^140140. M.
Keidar, A. Shashurin, S. Delaire, X. Fang, and I. I. Beilis, " 
Inverse heat flux in double layer thermal metamaterial," J. Phys. D:
Appl. Phys. 48, 485104 (2015). https://doi.org/10.1088/0022-3727/48/
48/485104
Concerning the mass production of hollow cathodes, advanced
manufacturing techniques (e.g., additive manufacturing) could play an
important role, especially with ongoing simplification of the cathode
design and manufacturing flow; mass production is necessary to meet
the current and future needs of ambitious satellite constellations.^
3232. D. R. Lev, I. G. Mikellides, D. Pedrini, D. M. Goebel, B. A.
Jorns, and M. S. McDonald, " Recent Progress in Research and
Development of Hollow Cathodes for Electric Propulsion," Rev. Mod.
Plasma Phys. 3, 6 (2019). https://doi.org/10.1007/s41614-019-0026-0
3. High current hollow cathodes
Hollow cathodes used in the present day ion thrusters and Hall
thrusters are capable of producing discharge currents of up to about
25 A. The next generation of Hall thrusters are designed to operate
in the 5-20 kW range and thus require discharge currents of less than
50 A. The design of high current hollow cathodes dated back to the
1970's, when they were developed to neutralize the beam from ion
sources intended for injection heating in fusion applications.^141
141. D. M. Goebel, J. T. Crow, and A. T. Forrester, " Lanthanum
hexaboride hollow cathode for dense plasma production," Rev. Sci.
Instrum. 49, 469-472 (1978). https://doi.org/10.1063/1.1135436 These
cathodes routinely in the range of 50 to over 500 A of discharge
current, which, for the purpose of this discussion, can be considered
as "high current" hollow cathodes. There are five major issues that
dominate the design of high current hollow cathodes:

1. Insert design, in terms of current density and evaporation;
2. Effective emission length;
3. Orifice plate design;
4. Heater design;
5. Suppression of erosion phenomena.

Theoretical modeling and numerical simulations prove to be effective
tools to design hollow cathodes, besides providing explanations of
experimental results in terms of performance and lifetime, as
described in Sec. III.
At temperatures over 1100 degC, BaO dispenser cathodes have significant
evaporation rates and tend to form tungstates. Both of these factors
limit their life in high current applications where power deposition
from cathode self-heating is significant. A preferable insert
material for high current hollow cathodes is LaB[6]: the higher
temperature operation and the higher emissivity of LaB[6] (compared
to BaO-W inserts) mean that the insert radiates effectively and
overheating is not a significant issue.
The plasma density profile along the axial direction in the insert
region is an important characteristic of high current hollow
cathodes, since it defines the plasma contact area and thus the
insert temperature profile. The axial uniformity in plasma density
affects the uniformity in both the insert temperature and the
evaporation rate. In addition, if the plasma density is excessively
low close to the insert upstream end, the thermionic emission of
electrons can be limited by space-charge effects, thus lowering the
current provided by the insert. Operation at higher discharge current
and higher gas flow rates often required by higher power thrusters
tends to constrict the plasma in the downstream portion of the
insert, limiting the effective emission length. The only solution is
to enlarge the cathode diameter, selecting larger insert and orifice
diameters, to operate the cathode in the nominal 1-Torr pressure
range.^3939. D. M. Goebel and I. Katz, Fundamentals of Electric
Propulsion: Ion and Hall Thrusters ( John Wiley & Sons, NJ, USA,
2008).
The maximum allowed current of a hollow cathode is often limited by
the orifice plate, since the orifice dimensions drive the current
density of the electrons drained from the insert, ultimately
affecting the growth of instabilities and energetic ion production in
the cathode plume. The orifice size also determines the pressure
inside the cathode for a given gas flow;^142142. D. M. Goebel, K. K.
Jameson, and R. R. Hofer, " Hall thruster cathode flow impacts on
cathode coupling and cathode life," J. Propul. Power 28, 355-363
(2012). https://doi.org/10.2514/1.B34275 as described previously,
this would impact the plasma contact area, the required insert
temperature to produce the discharge current, and therefore the
insert life. Finally, orifice plate heating is significant in high
current hollow cathodes,^143143. D. M. Goebel and E. Chu, " High
current lanthanum hexaboride hollow cathode for high power hall
thrusters," J. Propul. Power 30, 35-40 (2014). https://doi.org/
10.2514/1.B34870 and larger orifice plates are required to radiate
the power away. High current hollow cathodes have large radiation and
conduction areas and so require high power (200-400 W), high
temperature (>1400 degC) coaxial sheathed heaters or filament heaters
wound in an insulating mandrel around the cathode tube. Conventional
BaO-W dispenser hollow cathodes use coaxial sheathed tantalum heaters
with a MgO powdered insulation capable of nominally withstanding up
to about 100 W of power. High current LaB[6] hollow cathodes
typically use a tantalum sheathed-heater that incorporates
high-temperature alumina-powder insulation.^143143. D. M. Goebel and
E. Chu, " High current lanthanum hexaboride hollow cathode for high
power hall thrusters," J. Propul. Power 30, 35-40 (2014). https://
doi.org/10.2514/1.B34870 Alternative heaters based on refractory
metal filaments in ceramic mandrels or thin film heaters on ceramic
substrates are under development for this application.^144144. M.
Celik and H. Kurt, " Ferromagnetic enhanced inductively coupled
plasma cathode for thruster ion neutralization," AIP Conf. Proc. 2011
, 090022 (2018). https://doi.org/10.1063/1.5053403
Operation of hollow cathodes at high discharge currents tends to
generate ionization instabilities or current-driven turbulent ion
acoustic instabilities in the near cathode plume.^111111. D. M.
Goebel, K. K. Jameson, I. Katz, and I. G. Mikellides, " Potential
fluctuations and energetic ion production in hollow cathode
discharges," Phys. Plasmas 14, 103508 (2007). https://doi.org/10.1063
/1.2784460 These result in the energetic ion generation that erodes
the cathode and keeper orifice plate and limits the cathode life.
These modes are avoided in lower current hollow cathodes by means of
a particular selection of the cathode orifice diameter and the mass
flow rate, at a fixed discharge current. However, the same solution
is not sufficient in the case of high current hollow cathodes, where
exceptional means are needed to suppress or damp the instabilities.
The injection of additional neutral gas in the near plume of the
cathode has been found to successfully damp the ionization and ion
acoustic instabilities. An increase in the cathode mass flow rate to
damp the instabilities is not a recommended solution since, as
described above, the higher internal pressure constrains the plasma
in the downstream portion of the insert, lowering the contact area
thus affecting the lifetime. Nevertheless, a propellant source
similar to the cathode mass flow rate can be added externally to the
cathode or into the plume through the cathode to keeper gap to damp
the instabilities. The 2.1-cm-dia. X3 cathode was provided with an
additional gas feed external to the cathode orifice plate for all the
operating points from 200 A to 330 A of discharge current. Figure 14
(c) shows the X3 cathode with the external gas injectors. High
current hollow cathodes that are capable of producing 50 to 300 A of
discharge current are available now for development as propulsion
cathodes. Achieving higher current with long life will require larger
diameter inserts to provide more area for electron emission, larger
insert IDs for sufficient penetration of the plasma density upstream
for complete contact area with the insert, thicker inserts for longer
life, larger cathode orifice plates to radiate the power away, higher
power heater designs, and optimized external gas injection schemes.
Hollow cathodes in the range 50-300 A are now under development for
electric propulsion applications.^145,146145. B. A. Jorns, I. G.
Mikellides, and D. M. Goebel, " Ion acoustic turbulence in a 100-A
LaB[6] hollow cathode," Phys. Rev. E 90, 063106 (2014). https://
doi.org/10.1103/PhysRevE.90.063106146. E. Chu, D. M. Goebel, and R.
E. Wirz, " Reduction of energetic ion production in hollow cathodes
by external gas injection," J. Propul. Power 29, 1155-1163 (2013).
https://doi.org/10.2514/1.B34799 Higher current levels with extended
lifetime will be achieved selecting inserts with larger Inside
Diameters (IDs), to increase the emission surface and to enhance the
plasma penetration in the upstream direction for a total contact with
the insert, increased insert thicknesses to extend the lifetime,
larger orifice plates to improve the power radiation, more powerful
heater designs, and solutions to externally inject additional gas in
the near plume. Despite many of the advantages of LaB6, namely high
current capability with long lifetime (tens of thousands of hours),
low sensitivity to contaminants, and the possibility to sustain the
heating due to high current operation, new materials with low work
function and evaporation rate are under study. The theoretical study
of cathode operation, thermal behavior, and plasma plume
instabilities deserves to be pursued to achieve fully predictive
capabilities of the design codes.
III. MODELING AND SIMULATION: CHALLENGES AND FRONTIERS
Section:
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A. Modeling approaches
Numerical modeling and simulations are very powerful tools; their use
can drastically reduce the time and resources needed to design, test,
and optimize space propulsion thrusters. Moreover, modeling and
numerical simulations have become even more important for
miniaturized plasma thrusters, since the reduction of the scale of
the device inevitably results in increasing difficulty and
invasiveness of the direct measurement approaches. In addition, with
recent advances in in the high-performance computer (HPC) technology,
the high-fidelity of reproduction and rapid execution time of
numerical models are improving quickly. As a proof of the importance
of numerical modeling in the electric propulsion community, a
dedicated project named LANDMARK^148148. See https://
www.landmark-plasma.com for LANDMARK: Low temperAture magNetizeD
plasMA benchmaRKs; accessed June 2019. (Low temperAture magNetizeD
plasMA benchmaRKs) has been developed in the last two years. The
project aims to (1) provide an open forum for evaluating methods used
to describe plasma transport in nonfusion magnetized plasmas (e.g.,
ion sources, Hall thrusters (HTs), magnetrons, cusped-field
thrusters, etc.); (2) define benchmark test cases for full-kinetic,
fluid, and hybrid methods; (3) address physics issues linked to the
questions of anomalous transport across magnetic field,
instabilities, plasma-wall interactions, and their possible effects
on particle and energy transport; (4) facilitate international
collaboration and promote mutual understanding among researchers.
B. Kinetic techniques
The full kinetic description has often been applied to HT
configurations. Since electron thermalization and isotropization
rates are quite low in HTs, kinetic approaches are more suitable to
represent the important deviations of electron distribution functions
from the Maxwellian one. Furthermore, kinetic approaches are of ab
initio type and do not require any empirical adjustable parameter to
fit the experimental current. Among the different kinetic techniques,
the Particle-in-Cell-Monte Carlo Collision (PIC-MCC)^149149. C. K.
Birdsall and A. B. Langdon, Plasma Physics via Computer Simulation ( 
Taylor and Francis, 2005). model in the electrostatic approximation
is the one that is most commonly used. It consists of a mixed
Lagrangian-Eulerian (particle-mesh) solution of the coupled
Boltzmann-Poisson equations. By means of the Klimontovich-Dupree
representation of distribution functions, electron and ion Boltzmann
equations reduce to the solution of equations of motion for
macroparticles (clouds of real particles representing small regions
of the phase space). Figure 15 illustrates the typical PIC-MCC cycle.
The charge density is deposited on a spatial mesh (the size of which
must be smaller than the Debye length, step 3) where the electric
potential is solved (step 4) and from where the electric field is
interpolated back to the macroparticle locations (step 5). After
pushing the virtual particle (step 1) and before restarting the PIC
cycle again, a MCC^150150. F. Taccogna, " Monte Carlo collision
method for low temperature plasma simulation," J. Plasma Phys. 81,
305810102 (2015). https://doi.org/10.1017/S0022377814000567 module
(step 2) is called to process volumetric (i.e., electron-neutral,
ion-neutral, and Coulomb collisions) or surface events (i.e.,
secondary electron emission,^151151. M. Villemant, P. Sarrailh, M.
Belhaj, C. Inguimbert, L. Garrigues, and C. Boniface, " Electron
emission for Hall thruster plasma modelling," in Proceedings of the
35th International Electric Propulsion Conference, the Electric
Rocket Propulsion Society, Atlanta, GE (2017), Paper No.
IEPC-2017-366. ion sputtering,^152152. I. D. Boyd and M. L. Falk, " A
review of spacecraft material sputtering by Hall thruster plumes,"
AIAA Paper 2001-3353, 2001. etc.). PIC-MCC is a very powerful
numerical tool that allows for a very accurate and extremely detailed
analysis of plasma and discharge parameters. However, there are
important constraints associated with PIC-MCC methods. In the
explicit version where the electric field is supposed to be constant
during one time step, the integration time step must be less than the
inverse of the plasma frequency. The grid spacing must also be
limited to make sure that one particle does not move over more than
one grid interval during the time step. Another constraint is that
the number of particles per cell of the simulation must be large
enough to avoid statistical errors and numerical heating.
figure
FIG. 15. Diagram showing one integration time steps in a PIC MCC
simulation. Adapted with permission from J. Appl. Phys. 121, 011101
(2017). Copyright 2017 AIP Publishing.^147147. J.-P. Boeuf, " 
Tutorial: Physics and modeling of Hall thrusters," J. Appl. Phys. 121
, 011101 (2017). https://doi.org/10.1063/1.4972269

  * PPT|
  * High-resolution

The most important features of the HT PIC-MCC models are as follows:

(i)   Solution of the Poisson equation for the self-consistent
      electric field. It allows resolving the deviation from the
      quasineutrality in the plasma-wall transition regions.
(ii)  Detailed description of the electron-wall interactions.^153
      153. A. Dominguez-Vazquez, F. Taccogna, and E. Ahedo, " 
      Particle modeling of radial electron dynamics in a
      controlled discharge of a Hall thruster," Plasma Sources
      Sci. Technol. 27, 064006 (2018). https://doi.org/10.1088/
      1361-6595/aac968 With a high surface-to-volume ratio,
      plasma-wall interactions play an important role, not only
      as a source of energy loss but also as an active source of
      particle and energy terms.
(iii) Ability to reveal microinstabilities and self-organized
      structures typical of ExB partly magnetized low temperature
      plasma devices, such as electron E x B drift,^154,155154.
      T. Lafleur, S. D. Baalrud, and P. Chabert, " 
      Characteristics and transport effects of the electron drift
      instability in Hall-effect thrusters," Plasma Sources Sci.
      Technol. 26, 024008 (2017). https://doi.org/10.1088/
      1361-6595/aa56e2155. F. Taccogna, P. Minelli, Z. Asadi, and
      G. Bogopolsky, " Numerical studies of the ExB electron
      drift instability in Hall thrusters," Plasma Sources Sci.
      Technol. 28, 064002 (2019). https://doi.org/10.1088/
      1361-6595/ab08af spoke,^156156. K. Matyash, R. Schneider,
      S. Mazouffre, S. Tsikata, and L. Grimaud, " Rotating spoke
      instabilities in a wall-less Hall thruster: Simulations,"
      Plasma Sources Sci. Technol. 28, 044002 (2019). https://
      doi.org/10.1088/1361-6595/ab1236 sheath,^157157. F.
      Taccogna, S. Longo, M. Capitelli, and R. Schneider, " 
      Anomalous transport induced by sheath instability in Hall
      effect thrusters," Appl. Phys. Lett. 94, 251502 (2009).
      https://doi.org/10.1063/1.3152270 and two-stream^158158. D.
      Sydorenko, A. Smolyakov, I. Kaganovich, and Y. Raitses, " 
      Effects of non-Maxwellian electron velocity distribution
      function on two-stream instability in low-pressure
      discharges," Phys. Plasmas 14, 013508 (2007). https://
      doi.org/10.1063/1.2435315 instabilities. Detailed
      description of methods, advanced numerical algorithms, and
      high-performance computing techniques applied to PIC-MCC
      models can be found in the recent review publications.^
      159,160159. F. Taccogna and L. Garrigues, " Latest Progress
      in Hall Thrusters Plasma Modelling," Rev. Mod. Plasma Phys.
      3, 12 (2019). https://doi.org/10.1007/s41614-019-0033-1160.
      B. Chaudhury et al., " Hybrid parallelization of particle
      in cell monte carlo collision (PIC-MCC) algorithm for
      simulation of low temperature plasmas," in Software
      Challenges to Exascale Computing. SCEC 2018. Communications
      in Computer and Information Science, Vol 964, edited by A.
      Majumdar and R. Arora ( Springer, Singapore, 2019).

Figure 16 shows examples of self-organized structures detected by the
PIC-MCC models. In Fig. 16(a), the temporal evolution of the
azimuthal profiles of electron density is reported. It is evident
that the electron E x B drift instability is characterized by a
nonlinear evolution toward longer wavelengths by an inverse energy
cascade. Figure 16(b) reports the m = 1 spoke instability rotating
with a velocity of 6.5 km/s. Both phenomena lead to similar
high-frequency electric field oscillations characterized by a
wavelength of mm-scale, frequency of few megahertz, and amplitudes of
the order of 100 V/cm that have also been experimentally observed^161
161. S. Tsikata, N. Lemoine, V. Pisarev, and D. Gresillon, " 
Dispersion relations of electron density fluctuations in a Hall
thruster plasma, observed by collective light scattering," Phys.
Plasmas 16, 033506 (2009). https://doi.org/10.1063/1.3093261 and are
considered as very effective in inducing the anomalous electron cross
field transport.^163,164163. M. Tajmar, R. Sedmik, and C.
Scharlemann, " Numerical simulation of SMART-1 Hall-thruster plasma
interactions," J. Propul. Power 25, 1178-1188 (2009). https://doi.org
/10.2514/1.36654164. K. Shan, Y. Chu, Q. Li, L. Zheng, and Y. Cao, " 
Numerical Simulation of Interaction between Hall Thruster CEX Ions
and SMART-1 Spacecraft," Math. Probl. Eng. 2015, 418493. https://
doi.org/10.1155/2015/418493
figure
FIG. 16. (a) Temporal evolution of the electron density profile along
the E x B direction y in the acceleration region of HT. (b) Evolution
of the plasma density 3 mm above the anode during the spoke cycle.
Reprinted with permission from Matyash et al., Proceedings of the
36th International Electric Propulsion Conference, Vienna, Austria,
September 15-20 (2019), Paper No. IEPC-2019-437 (2019). Copyright
2019 ERPS.^162162. K. Matyash and R. Schneider, " 3D simulation of
rotating spoke in a wall-less Hall thruster," in Proceedings of the
36th International Electric Propulsion Conference, Vienna, Austria,
15-20 September (2019), Paper No. IEPC-2019-437.

  * PPT|
  * High-resolution

The primary challenge concerning PIC-MCC codes is being able to
describe HTs through a full three-dimensional representation. It may
be possible to address this challenge by increasing their scalability
up to 10^5 processors using optimized Poisson equation solvers,
implementing particle sorting techniques, and taking advantage of the
particle domain decomposition on the modern supercomputer
architecture [the central processing unit (CPU)/graphic processing
unit (GPU) combination].

* Kinetic PIC methods are extremely powerful and convenient tools
  to significantly cut off the time and resources need for
  optimization of plasma thrusters; further development of this
  technique is in high demand.
* Kinetic numerical modeling is efficient for investigating
  self-organized structures and microinstabilities typical of E x
  B partly magnetized low temperature plasma devices.

C. Direct simulation Monte Carlo (DSMC) and atomistic simulation
techniques
The Direct Simulation Monte Carlo (DSMC) method is actually a class
of kinetic methods, which uses probabilistic (Monte Carlo) simulation
to solve the Boltzmann equation (Fig. 17). As a random particle-based
method, DSMC can be used to solve dilute gas flow problems.
Originally developed by Bird more the 50 years ago, DSMC has evolved
into becoming one of the most frequently used approaches for
simulating the flows of gas within the so-called nonequilibrium
Knudsen number regime.^165165. G. A. Bird, Molecular Gas Dynamics an
d the Direct Simulation of Gas Flows ( Oxford University Press,
1994). In this approach, each individual particle embodies a
significant number of gas species (i.e., real atoms or molecules).
This notably reduces the computational power needed to execute the
simulation when compared to molecular dynamics (MD) and other fully
deterministic approaches. These individual particles are allowed to
move freely in space, characterized by their individual velocity and
the local time step. The particles can engage into interactions with
other particles, as well as with the margins that confine the system.
The collisions between the particles are considered stochastically
after all individual particle movements have occurred. In doing so,
as it progresses, the simulation reflects the physical processes that
take place in a real gas instead of trying to resolve Newton's
equations of motion for a large set of individual atoms/molecules, as
is the case in fully deterministic MD methods.^166166. C. White, M.
K. Borg, T. J. Scanlon, S. M. Longshaw, B. Johnd, D. R. Emerson, and
J. M. Reese, " dsmcFoam+: An OpenFOAM based direct simulation Monte
Carlo solver," Comput. Phys. Commun. 224, 22-43 (2018). https://
doi.org/10.1016/j.cpc.2017.09.030
figure
FIG. 17. (a) Flow chart of a basic DSMC time-integration scheme.
Reprinted with permission from White et al., Comput. Phys. Commun.
224, 223 (2018). Copyright 2018 Author(s), licensed under a Creative
Commons CC BY license.^166166. C. White, M. K. Borg, T. J. Scanlon,
S. M. Longshaw, B. Johnd, D. R. Emerson, and J. M. Reese, " 
dsmcFoam+: An OpenFOAM based direct simulation Monte Carlo solver,"
Comput. Phys. Commun. 224, 22-43 (2018). https://doi.org/10.1016/
j.cpc.2017.09.030 (b) and (c) Plasma potential distributions obtained
by the three-dimensional IFE-PIC-MCC code with the DSMC technique
applied to model neutral atoms for the numerical simulations of
SMART-1 spacecraft that had traveled to the Moon using a PPS-1350
Hall thruster.^163163. M. Tajmar, R. Sedmik, and C. Scharlemann, " 
Numerical simulation of SMART-1 Hall-thruster plasma interactions,"
J. Propul. Power 25, 1178-1188 (2009). https://doi.org/10.2514/
1.36654 Reprinted with permission from Shan et al., Math. Probl. Eng.
2015, 418493. Copyright 2018 Author(s), licensed under a Creative
Commons Attribution License.^164164. K. Shan, Y. Chu, Q. Li, L.
Zheng, and Y. Cao, " Numerical Simulation of Interaction between Hall
Thruster CEX Ions and SMART-1 Spacecraft," Math. Probl. Eng. 2015,
418493. https://doi.org/10.1155/2015/418493 These studies have
revealed that the maximum disturbance normal force can reach 1% of
the main thrust produced by the thruster. While this value is small,
it may be important for special astronomical missions requiring very
high attitude accuracy for the spacecraft.

  * PPT|
  * High-resolution

There are a wide variety of collision phenomena that can be described
by means of the DSMC method. These include the exchange of momentum,
charge, and internal energy between the colliding particles, as well
as chemical reactions that make take place when particles interact.
The properties of individual particles are time averaged to obtain
the average characteristics of the gas flow, including its density,
velocity, and pressure. It is possible to stimulate unsteady flows by
considering the average properties over discrete periods of time or
by applying ensemble averaging.^167167. I. D. Boyd, " Extensive
validation of a Monte Carlo model for hydrogen arcjet flow fields,"
J. Propul. Power 13, 775-782 (1997). https://doi.org/10.2514/2.5232
This method is particularly suitable for simulating hybrid
particle-fluid systems, where electrons impacting on the heavy
particles are defined as a fluid, and the particles represent the
heavy species.^168,169168. I. D. Boyd and J. T. Yim, " Modeling of
the near field plume of a Hall thruster," J. Appl. Phys. J. Appl.
Phys. 95(9), 4575-4584 (2004). https://doi.org/10.1063/1.1688444169.
D. Boyd, " Numerical modeling of spacecraft electric propulsion
thrusters," Prog. Aerosp. Sci. 41(8), 669-687 (2005). https://doi.org
/10.1016/j.paerosci.2006.01.001 Specifically, when using the DSMC
technique, the principal elastic and charge exchange collisions can
be included in the model, thus ensuring the sufficient level of
accuracy. In the No-Time-Counter method typical for DSMC,^170170. S.
Cheng, M. Santi, M. Celik, M. Martinez-Sanchez, and J. Peraire, " 
Hybrid PIC-DSMC simulation of a Hall thruster plume on unstructured
grids. Hybrid PIC-DSMC simulation of a Hall thruster plume on
unstructured grids," Comput. Phys. Commun. 164, 73-79 (2004). https:/
/doi.org/10.1016/j.cpc.2004.06.010 the selection and rejections of
the pairs of individual particles for collisions within cells are
performed statistically. It is possible to assign distinct
macroparticle weightings to individual heavy species. Since this
method is very powerful for modeling and studying phenomena in very
rarefied gases, it could be used, e.g., for investigating the
interaction of plasma jets with the background gases.^171,172171. Y.
Yue, F. Ma, W. Gong, J. Li, F. Yu, L. Nie, Y. Xian, K. Bazaka, X. Lu,
and K. Ostrikov, " Radial constraints and the polarity mechanism of
plasma plume," Phys. Plasmas 25, 103510 (2018). https://doi.org/
10.1063/1.5052133172. W. Gong, Y. Yue, F. Ma, F. Yu, J. Wan, L. Nie,
K. Bazaka, Y. Xian, X. Lu, and K. Ostrikov, " Control of radial
propagation and polarity in a plasma jet in surrounding Ar," Phys.
Plasmas 25, 013505 (2018). https://doi.org/10.1063/1.5010993 Using
this technique, it has been demonstrated that the characteristics of
the jet of plasma are highly affected by the nature of the
background. Since these parameters are of importance for propulsor
incorporation into the spacecraft, experimental parameters obtained
in the vacuum tank environment should be analyzed with a degree of
caution.^170,173170. S. Cheng, M. Santi, M. Celik, M.
Martinez-Sanchez, and J. Peraire, " Hybrid PIC-DSMC simulation of a
Hall thruster plume on unstructured grids. Hybrid PIC-DSMC simulation
of a Hall thruster plume on unstructured grids," Comput. Phys.
Commun. 164, 73-79 (2004). https://doi.org/10.1016/j.cpc.2004.06.010
173. M. Celik, M. Santi, S. Cheng, M. Martinez-Sanchez, and J.
Peraire, " Hybrid-PIC simulation of a Hall thruster plume on an
unstructured grid with DSMC collisions," in 28th International
Electric Propulsion Conference, Toulouse, France (2003), Paper No.
IEPC-03-134. Not surprisingly, this method is also promising for
studying the interactions of electric thruster-produced ions with
spacecraft. Indeed, this problem features very rarefied ion fluxes
that are hard to model but which could, at a long time runs of
several years required for interplanetary travels, cause severe
damage to the structure of spacecraft and instruments installed on
board of these space assets.^164164. K. Shan, Y. Chu, Q. Li, L.
Zheng, and Y. Cao, " Numerical Simulation of Interaction between Hall
Thruster CEX Ions and SMART-1 Spacecraft," Math. Probl. Eng. 2015,
418493. https://doi.org/10.1155/2015/418493
Atomistic simulation techniques are mainly used to simulate the
plasma-material interactions, which is very important for predicting
material wear and sputtering and for modeling service life of the
thrusters, the components of which are subject to strong ion,
electron, and heat fluxes, e.g., accelerating grids of ion thrusters^
174174. M. Sangregorio, K. Xie, N. Wang, N. Guo, and Z. Zhang, " Ion
engine grids: Function, main parameters, issues, configurations,
geometries, materials and fabrication methods," Chin. J. Aeronaut. 31
, 1635-1649 (2018). https://doi.org/10.1016/j.cja.2018.06.005 and
walls of acceleration channel in Hall thrusters.^175,176175. R. W.
Conversano, D. M. Goebel, R. R. Hofer, I. G. Mikellides, I. Katz, and
R. E. Wirz, in paper presented at The Joint 30th ISTS, 34th IEPC and
6th NSAT Conference, Kobe-Hyogo, Japan, 4 July (2015), Paper No.
IEPC-2015-100/ISTS-2015-b-100.176. L. Grimaud and S. Mazouffre, J.
Appl. Phys. 122, 033305 (2017). https://doi.org/10.1063/1.4995285
Moreover, special configurations of the magnetic field and other
parameters in the acceleration channel of Hall thrusters could be
organized to significantly prolong the deposition area in the
channel, where redeposition of the sputtered material occurs, and
hence, atomistic simulations would be required to model the growth of
surface structures under the effect of plasma^177,178177. Y. Ding, Y.
Xu, W. Peng, L. Wei, H. Su, H. Sun, P. Li, H. Li, and D. Yu, J. Phys.
D: Appl. Phys. 50, 145203 (2017). https://doi.org/10.1088/1361-6463/
aa6019178. D. de Faoite, D. Browne, F. R. Chang-Diaz, and K. Stanton,
" A review of the processing, composition, and temperature-dependent
mechanical and thermal properties of dielectric technical ceramics,"
J. Mater. Sci. 47, 4211-4235 (2012). https://doi.org/10.1007/
s10853-011-6140-1 and to ensure healing and self-regeneration of the
surfaces.^139,179139. I. Levchenko, S. Xu, G. Teel, D. Mariotti, M.
L. R. Walker, and M. Keidar, " Recent progress and perspectives of
space electric propulsion systems based on smart nanomaterials," Nat.
Commun. 9, 879 (2018). https://doi.org/10.1038/s41467-017-02269-7179.
I. Levchenko, K. Bazaka, T. Belmonte, M. Keidar, and S. Xu, " 
Advanced materials for next generation spacecraft," Adv. Mater. 30,
1802201 (2018). https://doi.org/10.1002/adma.201802201 Evidently,
selection of such parameters is not a trivial task, and sophisticated
atomic scale simulations could be a powerful tool to ensure long
service life of the thrusters through the careful modeling of the
materials-plasma interactions. While a detailed discussion of the
atomic simulations is outside of the scope of this article, it is
worth emphasizing their current and future importance for the design
and optimization of future advanced thrusters. In general, the atomic
scale simulations can be broadly categorized as those based on
quantum mechanisms, i.e., those based on the wave function and
density function and those based on classical principles. The latter
type can itself be divided into reactive and nonreactive models. In
the former, the simulation allows for the chemicals bonds to form and
break. Further details about specific applications of atomic
simulations for modeling sputtering and growth in plasma can be found
elsewhere, with a view to implement this technique for the further
advancement of electric propulsion systems.^180,181180. M. Shariat,
B. Shokri, and E. C. Neyts, " On the low-temperature growth mechanism
of single walled carbon nanotubes in plasma enhanced chemical vapor
deposition," Chem. Phys. Lett. 590, 131-135 (2013). https://doi.org/
10.1016/j.cplett.2013.10.061181. Q. Xiang, X. Ma, D. Zhang, H. Zhou,
Y. Liao, H. Zhang, S. Xu, I. Levchenko, and K. Bazaka, " Interfacial
modification of titanium dioxide to enhance photocatalytic efficiency
towards H2 production.," J. Colloid Interf. Sci. 556, 376-385 (2019).
https://doi.org/10.1016/j.jcis.2019.08.033
D. Fluid approach
Fluid-based models are valid when the distributions of particles are
close to equilibrium, i.e., the pressure is high enough for the
charged particles to collide between themselves rather than with the
walls, as is the case in the electromagnetic engines and thermionic
cathodes (see Sec. II C for challenges in the latter category).
Plasma properties are described through density, mean velocity, and
mean energy that are the solution of a system of macroscopic fluid
equations. In electromagnetic thrusters, fluid equations are coupled
with Maxwell's equations^182,183182. H. P. Wagner, H. J. Kaeppeler,
and M. Auweter-Kurtz, " Instabilities in MPD thruster flows: 2.
Investigation of drift and gradient driven instabilities using
multifluid plasma models," J. Phys. D: Appl. Phys. 31, 529-541
(1998). https://doi.org/10.1088/0022-3727/31/5/010183. I. Mikellides,
" Modeling and analysis of a megawatt-class magnetoplasmadynamic
thruster," J. Propul. Power 20, 204 (2004). https://doi.org/10.2514/
1.9246 to self-consistently determine the induced electric and
magnetic fields profiles.^184-186184. R. Martorelli, T. Lafleur, A.
Bourdon, and P. Chabert, " Comparison between ad-hoc and
instability-induced electron anomalous transport in a 1D fluid
simulation of Hall-effect thruster," Phys. Plasmas 26, 083502 (2019).
https://doi.org/10.1063/1.5089008185. Z. Li and D. Livescu, " 
High-order two-fluid plasma solver for direct numerical simulations
of plasma flows with full transport phenomena," Phys. Plasmas 26,
012109 (2019). https://doi.org/10.1063/1.5082190186. K. Hara, " 
Non-oscillatory quasineutral fluid model of cross-field discharge
plasmas," Phys. Plasmas 25, 123508 (2018). https://doi.org/10.1063/
1.5055750 The magneto-hydrodynamic code MACH developed by the US Air
Force research laboratory has successfully been used to model the
operation of a self-field MPD thruster in a real thruster geometry. 
Figure 18 shows the typical results of the MACH code in its 2D
axisymmetric version. The results show an incomplete ionization of
the hydrogen propellant and that the mass expansion in the vicinity
of the anode contributes to the thrust.^187187. P. G. Mikellides, " 
Design and operation of MW-class MPD thrusters, Part I: Numerical
modelling," in Proceedings of the 27th International Electric
Propulsion Conference, Pasadena, CA, October (2001), Paper No.
IEPC-2001-124. The complexity of electrodynamic thrusters in terms of
dynamics of instabilities in 3D highlights the considerable
challenges fluid modeling must overcome in the coming years.
figure
FIG. 18. MACH 2 two-dimensional distributions for a 10 kA MPD
thruster, (top) average degree of ionization, and (bottom) mass
density. Reprinted with permission from P. G. Mikellides, Proceedings
of the 27th International Electric Propulsion Conference, Pasadena,
CA, October 2001, Paper No. IEPC-2001-124. Copyright 2001 IEPC.^187
187. P. G. Mikellides, " Design and operation of MW-class MPD
thrusters, Part I: Numerical modelling," in Proceedings of the 27th
International Electric Propulsion Conference, Pasadena, CA, October
(2001), Paper No. IEPC-2001-124.

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E. Fluid-hybrid technique
In a fluid-hybrid approach, the system of macroscopic fluid equations
for ions has been replaced with a kinetic description, where the ion
energy distribution is self-consistently calculated. In electrostatic
thrusters, the ion energy distribution varies in time and space and
corresponds to a peaked distribution far from equilibrium. These
properties have to be self-consistently determined. In that way, a
hybrid approach is often preferred over other methods. In ion
thrusters, the modeling efforts are mainly related to ion optics and
its consequences for grid erosion. In most instances, the fluid
transport of electrons is simplified through a Boltzmann relation
with a given electron temperature that makes electrons immediately
respond to the electric potential variations. Poisson's equation is
solved to calculate the electric field profile due to the space
charge face to grid apertures.^188-190188. J. Wang, J. Polk, J.
Brophy, and I. Katz, " Three-dimensional particle simulations of
ion-optics plasma flow and grid erosion," J. Propul. Power 19, 1192
(2003). https://doi.org/10.2514/2.6939189. M. Chen, A. Sun, C. Chen,
and G. Xia, " Particle simulation of grid system for krypton ion
thrusters," Chin. J. Aeronaut. 31, 719-726 (2018). https://doi.org/
10.1016/j.cja.2018.01.020190. B. Jorns, " Predictive, data-driven
model for the anomalous electron collision frequency in a Hall effect
thruster," Plasma Sources Sci. Technol. 27, 104007 (2018). https://
doi.org/10.1088/1361-6595/aae472 Figure 19 illustrates a comparison
of the effect of charge exchange collisions on grid erosion for an
ion thruster working with xenon and krypton propellants. 3D
Commercial software can now be used to properly define the best
design for the grid system according to the thruster operation, with
current challenges revolving around the availability of basic data of
ion sputtering for different grid materials.
figure
FIG. 19. Distribution of the charge exchange collision rate and its
influence on current density on the accelerator grid. (a) and (b)
charge exchange (CEX) collision rate of Kr and Xe ion thrusters,
respectively. (c) and (d) Current density on the accelerator grid of
Kr and Xe ion thrusters by CEX ion impact. Reprinted with permission
from Chen et al., Chin. J. Aeronaut. 31, 719-726 (2018). Copyright
2018 Author(s), licensed under a Creative Commons CC BY-NC-ND
license.^189189. M. Chen, A. Sun, C. Chen, and G. Xia, " Particle
simulation of grid system for krypton ion thrusters," Chin. J.
Aeronaut. 31, 719-726 (2018). https://doi.org/10.1016/
j.cja.2018.01.020

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As HTs are not space-charge limited and since the self-induced
magnetic field can be ignored, the self-consistent electric field is
deduced from the electron fluid transport assuming the quasineutral
hypothesis. Sheath properties (including the effects of secondary
electron emission and sputtering) are analytically described.^191191.
K. Hara, " An overview of discharge plasma modeling for Hall effect
thrusters," Plasma Sources Sci. Tech. 28, 044001 (2019). https://
doi.org/10.1088/1361-6595/ab0f70 Hybrid approaches have been highly
successful in describing the HT operation with the prediction of
so-called breathing mode and transit time oscillations, as
illustrated in Fig. 20.
figure
FIG. 20. (Top) Results from the 1D axial hybrid model. (a) Neutral
density (maximum 1.6 x 10^19 m^-3) and (b) plasma density (maximum
1.6 x 10^18 m^-3). Reprinted with permission from Darnon et al., IEEE
Trans. Plasma Sci. 27, 98 (1999). Copyright 1999 IEEE.^199199. F.
Darnon, L. Garrigues, J. P. Boeuf, A. Bouchoule, and M. Lyszyk, " 
Spontaneous oscillations in a Hall thruster," IEEE Trans. Plasma Sci.
27, 98 (1999). https://doi.org/10.1109/27.763063 (Bottom) Results
from the 2D (axial-radial) hybrid model. Discharge and ion currents
as a function of time show the breathing model oscillations at a
frequency of 20 kHz with superimposed ion transit time oscillations
at 200 kHz. Reprinted with the permission from Phys. Plasmas 10, 4886
(2004). Copyright 2004 AIP Publishing.^200200. J. Bareilles, G. J. M.
Hagelaar, L. Garrigues, C. Boniface, J. P. Boeuf, and N. Gascon, " 
Critical assessment of a two-dimensional hybrid Hall thruster model:
Comparisons with experiments," Phys. Plasmas 10, 4886 (2004).

  * PPT|
  * High-resolution

To enable further progress in the fluid and hybrid modeling of HTs, a
number of challenges need to be overcome. The first challenge
concerns present capability to propose efficient numerical schemes
able to capture the effect of nondiagonal terms in the tensor of
transport coefficients to be able to model a large variety of
magnetic field configurations.^192,193192. G. J. M. Hagelaar, " 
Modelling electron transport in magnetized low temperature discharge
plasmas," Plasma Sources Sci. Technol. 16, S57 (2007). https://
doi.org/10.1088/0963-0252/16/1/S06193. I. G. Mikellides and I. Katz,
" Numerical simulations of Hall-effect plasma accelerators on a
magnetic-field-aligned mesh," Phys. Rev. E 86, 046703 (2012). https:/
/doi.org/10.1103/PhysRevE.86.046703 The second and main challenge
concerns the inclusion of mechanisms responsible for anomalous
transport through electron-wave interactions (high frequency-small
scales and low frequency-large scales), as illustrated in Fig. 20,
and its implementation via wave-interaction equations^154,194,195154.
T. Lafleur, S. D. Baalrud, and P. Chabert, " Characteristics and
transport effects of the electron drift instability in Hall-effect
thrusters," Plasma Sources Sci. Technol. 26, 024008 (2017). https://
doi.org/10.1088/1361-6595/aa56e2194. M. K. Scharfe, C. A. Thomas, D.
B. Scharfe, N. Gascon, M. A. Cappelli, and E. Fernandez, " 
Shear-based model for electron transport in hybrid Hall thruster
simulations," IEEE Trans. Plasma Sci. 36, 2058 (2008). https://
doi.org/10.1109/TPS.2008.2004364195. M. A. Cappelli, C. V. Young, A.
Cha, and E. Fernandez, " A zero-equation turbulence model for
two-dimensional hybrid Hall thruster simulations," Phys. Plasmas 22,
114505 (2015). https://doi.org/10.1063/1.4935891 or analytical laws
derived from numerous experimental campaigns.^196196. T. Lafleur and
P. Chabert, " The role of instability-enhanced friction on
'anomalous' electron and ion transport in Hall-effect thrusters,"
Plasma Sources Sci. Technol. 27, 015003 (2018). https://doi.org/
10.1088/1361-6595/aa9efe
Finally, whatever is the type of the electric propulsion system being
considered, the study of interactions between the plume and the
satellites and the induced spacecraft charging is of considerable
importance. A hybrid approach assuming a Boltzmann equilibrium for
unmagnetized electrons is often the preferred method.
Three-dimensional large scale tools like the open-source SPIS
software^197,198197. T. Lafleur, R. Martorelli, P. Chabert, and A.
Bourdon, " Anomalous electron transport in Hall-effect thrusters:
Comparison between quasi- linear kinetic theory and particle-in-cell
simulations," Phys. Plasmas 25, 061202 (2018). https://doi.org/
10.1063/1.5017626198. See http://dev.spis.org/projects/spine/home/
spis for SPIS, the Spacecraft Plasma Interaction System; accessed May
2019. are able to contain all of the satellite geometry but with the
simplified boundary conditions for charged particle properties coming
from the thrusters. The coupling between refined models of electric
propulsion systems and larger scale plume-interaction tools,
validated with measurements, is crucial for the electric propulsion
community.^199,200199. F. Darnon, L. Garrigues, J. P. Boeuf, A.
Bouchoule, and M. Lyszyk, " Spontaneous oscillations in a Hall
thruster," IEEE Trans. Plasma Sci. 27, 98 (1999). https://doi.org/
10.1109/27.763063200. J. Bareilles, G. J. M. Hagelaar, L. Garrigues,
C. Boniface, J. P. Boeuf, and N. Gascon, " Critical assessment of a
two-dimensional hybrid Hall thruster model: Comparisons with
experiments," Phys. Plasmas 10, 4886 (2004).
IV. FRONTIERS AND OUTLOOK
Section:
[Choose                      ]
Previous sectionNext section
A. What does the future hold for electric and plasma propulsion
technology?
Given the current trends described in the reports coming out from
academic and industry stakeholders, three directions of high priority
can be identified: miniaturization, uptake of the advanced and
self-healing materials, and search for new device paradigms to widen
the niche of possible applications for plasma space propulsion.
1. Miniaturization
Our built environment is in the process of overwhelming
miniaturization. Handy, ultraminiaturized, multifunctional electronic
devices are among a wide range of inventions that are now penetrating
every facet of our life and revolutionizing how we deliver and
consume products and services.^201201. H. P. Zhou, X. Ye, W. Huang,
M. Q. Wu, L. N. Mao, B. Yu, S. Xu, I. Levchenko, and K. Bazaka, " 
Wearable, flexible, disposable plasma-reduced graphene oxide stress
sensors for monitoring activities in austere environments," ACS Appl.
Mater. Interfaces 11(16), 15122-15132 (2019). https://doi.org/10.1021
/acsami.8b22673 There is no doubt that miniaturization of space
assets is also steaming ahead, bringing along obvious advantages of
lower cost and advanced functionality, efficiency, and lifetime. Most
probably, miniaturization alone would likely to remain a key trend
and a major driver for the advancement of future spacecraft.
Miniaturization provides additional space--and the space is limited
even in space! This is particularly true for near-Earth orbits where
debris can be encountered more frequently than operational
satellites. Moreover, miniaturization in combination with the use of
small and ultrasmall satellites "en masse" means new
capabilities--which is the key aspect of current space technologies.
Miniaturization means reduced cost and hence much greater
affordability and easier access to space for those who need some
special functions but cannot spend millions to purchase the entire
launch. Examples include small scientific labs, private companies,
and universities. Most importantly, small satellites could form
networked distributed systems, i.e., dynamically changing, adaptive
constellations for the mission-oriented coordinated formation flights
of a large number of mini-satellites that feature expressive
capabilities not readily available when using several satellites with
the total mass similar to that of the net mass of the constellation.
New opportunities offered by these interconnected networks include
the widest-possible coverage of survey and information pickup; and
larger, of the constellation size, observation bases with the
relevant resolution and ability to collect and coherently process the
information inside the constellation. These features may open new
horizons for the efficient, robust space exploration.^55. I.
Levchenko, M. Keidar, J. Cantrell, Y.-L. Wu, H. Kuninaka, K. Bazaka,
and S. Xu, " Explore space using swarms of tiny satellites," Nature
562, 185 (2018). https://doi.org/10.1038/d41586-018-06957-2 This
holds true not only for the near Earth exploration and connectivity.
Small yet organized groups of small satellites at the orbits of the
Moon and Mars could be quite realistic and a much cheaper alternative
to large, heavy universal probes that require heavy launch vehicles
to reach remote planets. Recent studies suggest that deep-space
Cubesats are nearing reality.^202202. Success of tiny Mars probes
heralds new era of deep-space Cubesats; Accessed March 2019.
However, significant stumbling blocks still hinder the deployment of
organized mini-satellites, albeit launching them in hundreds at a
time is nowadays a routine practice (e.g., 104 satellites were
deployed by the Polar Satellite Launch Vehicle C37 mission on
February 15, 2017).^203203. Record launch included 100 small
satellites--Aerospace America; Accessed March 2019. Yet, many of these
assets can be described as passive spacecraft in that they have the
capacity to change orientation but not to conduct active maneuvers.
Whereas, for organized coordinated flight, spacecraft fitted with
highly efficient, reliable thrust systems that can maintain active
work and coherent maneuvering of small satellites within the
formation. On the other hand, at the power level of hundred and even
tens watts as required for typical Cubesats of one to ten U
form-factor, the efficiency of small thrusters is unacceptably low,
sometimes below 10%. Such low efficiency implies the need for
considerable quantities of propellant and electric power to be
carried on board, often at the expense of payload, and, consequently,
a reduced orbital service life.
B. How can we advance miniaturization of space propulsion systems?
Systems that rely on cold gas and hydrazine show suboptimal
performance with respect to specific impulses when their dimensions
are reduced to produce tens of watts. This is quite expected from the
physics point of view due to considerable hydraulic losses in the
accelerating channels and nozzles as a result of high
surface-to-volume ratios in radically scaled down systems. While
efforts have been made to enhance the specific impulse by employing
electric heating, the resulting hybrid thrusters did not feature
significantly improved efficiency. Moreover, they were cumbersome and
demanded the use of both electrical energy and chemical fuels, the
latter often being harmful and corrosive. Although they were used in
several missions, such systems did not find a niche in the space
technology.
Therefore, the current trend is "all-electric space thrust
platforms," the development of which is currently being driven by
many prominent industry players, e.g., by Airbus with its Eutelsat
172B launched on 2 June 2017.^204204. All-electric propulsion
satellites--Sparking a revolution in space; Accessed March 2019. These
systems are very flexible and diverse; their amazing assortment and
versatility are the most prominent signature of the electric thrust
platforms. To date, a wide range of electric thrusters has been
developed and tested in labs and directly in space. Several device
types could be highlighted as the major trends in the field:

* Hall thrusters that rely on a closed electron drift and deliver
  high thrust-to-power ratios and large thrust densities;
* ion thrusters that accelerate ions through a high electric
  potential applied between two metal grids and deliver low thrust
  density but very high specific impulse;
* magnetoplasmadynamic thrusters that accelerate plasma as a whole
  medium by means of an electric discharge between two electrodes;
* electrodeless systems with rotating and complex-shape magnetic
  fields, such as Rotamaks, helicon thrusters, and similar
  systems;
* electrospray thrusters of different structures, and
* printable cathode arc thrusters.

Every one of the aforementioned devices requires a special approach
to overcome the specific stumbling blocks that presently limit their
scale down and thus to achieve miniaturization. Several major trends
and approaches to achieve said miniaturization have already been
proposed.
1. Hall thrusters
Hall thrusters are now considered as a very promising propulsion
means for medium and large satellites and space probes. Thus,
considerable efforts are dedicated to their miniaturization toward
sizes compatible with Cubesats. An interesting and promising step
toward this goal is the invention and testing of the "cylindrical
Hall thrusters" featuring a simplified geometry without the central
cylindrical part. This configuration decreases the efficiency of the
device, yet it opens wide prospects for miniaturization by providing
a way to build a tiny acceleration channel with a very small
diameter. Underpinned by the pioneering works at the Princeton Plasma
Propulsion Laboratory, these thrusters have gained a wide recognition
and may be soon adapted to Cubesats.^205-207205. Y. Raitses and N. J.
Fisch, " Parametric investigations of a nonconventional Hall thruster
," Phys. Plasmas 8, 2579 (2001). https://doi.org/10.1063/1.1355318
206. Y. Raitses, A. Smirnov, and N. J. Fisch, " Cylindrical Hall
thrusters," AIAA Paper 2006-3245.207. Y. Raitses, E. Merino, and N.
J. Fisch, " Cylindrical Hall thrusters with permanent magnets," J.
Appl. Phys. 108, 093307 (2010). https://doi.org/10.1063/1.3499694
Hall thrusters developed and tested at the Space Propulsion Center in
Singapore (SPCS) combine a number of innovations, including novel
materials with exceptional properties for acceleration channels,
flexible permanent magnet-based magnetic circuits, and an innovative
cathode design. These technological innovations allowed the
development of a 10 W Hall thruster, a world record. Such a device
could typically be installed on 6U Cubesats.^208208. J. W. M. Lim, I.
Levchenko, S. Huang, L. Xu, R. Z. W. Sim, J. S. Yee, G.-C. Potrivitu,
Y. Sun, K. Bazaka, X. Wen, J. Gao, and S. Xu, " Plasma parameters and
discharge characteristics of lab-based kryptonpropelled miniaturized
Hall thruster," Plasma Sources Sci. Technol. 28, 064003 (2019).
https://doi.org/10.1088/1361-6595/ab07db
Another potential way to improve the efficiency of small Hall
thrusters is by using the so-called wall-less configuration where the
plasma discharge is shifted outside the channel, therefore
drastically reducing losses at the walls; it also makes the device
very simple and hence more reliable.^52-5652. J. Vaudolon, S.
Mazouffre, C. Henaux, D. Harribey, and A. Rossi, Appl. Phys. Lett.
107, 174103 (2015). https://doi.org/10.1063/1.493219653. S.
Mazouffre, S. Tsikata, and J. Vaudolon, J. Appl. Phys. 116, 243302
(2014). https://doi.org/10.1063/1.490496554. S. Mazouffre, L.
Grimaud, S. Tsikata, K. Matyash, and R. Schneider, Plasma Sources
Sci. Technol. 28, 054002 (2019). https://doi.org/10.1088/1361-6595/
ab07fc55. Y. Ding, L. Wang, H. Fan, H. Li, W. Xu, L. Wei, P. Li, and
D. Yu, " Simulation research on magnetic pole erosion of Hall
thrusters," Phys. Plasmas 26, 023520 (2019). https://doi.org/10.1063/
1.507704156. Y. Ding et al., Eur. Phys. J. Spec. Top. 226, 2945-2953
(2017). https://doi.org/10.1140/epjst/e2016-60247-y Although these
preliminary reports are encouraging and show stable operation and low
wear of the device, ionization remains to be increased, e.g., by
shaping the magnetic field, and the ion beam divergence angle has to
be reduced to increase performance metrics.
2. Ion thrusters
Ion thrusters are promising electric propulsion systems that are
currently being considered as promising candidate thrusters for
active maneuvers, orbit keeping, and gaining impulse for the
interplanetary missions. In these devices, the ion flux is
accelerated by the DC potential applied to the grids, delivering very
high specific impulse. However, unlike Hall thrusters, the ion
thrusters are characterized by lower thrust density attributed to the
electric space charge in the discharge chamber. This limits their
suitability for miniaturization. It may be possible to compensate
for, the low value of the thrust density by applying greater
accelerating voltage to the grids. Yet, this may be challenging to
realize in the miniaturized systems due to increased likelihood of
electric breakdowns owing to small gaps between the powered
electrodes, and thin insulators. It is possible that with the
development of sophisticated miniaturized semiconductor systems in
may e possible to sustain safe generation of high voltages on board
of Cubesats. For this reason, miniaturization of ion thrusters
requires advances in materials science and engineering, just as much
as progress in plasma physics and technology. Current efforts to
design the miniaturized ion thrusters include, e.g., the article in
Journal of Spacecraft and Rockets.^209209. R. W. Conversano and R. E.
Wirz, " Mission capability assessment of CubeSats using a miniature
ion thruster," J. Spacecr. Rockets 50, 1035-1046 (2013). https://
doi.org/10.2514/1.A32435 Busek Co. Inc., a private propulsion
company, has recently reported the radio frequency ion thruster of
1 cm size with the power of about 10 W, designed specifically to
address the needs of Cubesats.^210210. BUSEK Company. Accessed March
2019.
3. Magnetoplasmadynamic thrusters
Magnetoplasmadynamic thrusters accelerate the ionized propellant as
the entire medium. As such, their thrust density is sufficiently high
to render these devices suitable to be used in microthrust
configurations. Pulsed thrusters have a range of applications in
small satellites and Cubesats of various sizes, including the
smallest ones. In a microcathode form-factor, they can be used in
Cubesats of 1 U form-factor and smaller, mainly for precise attitude
control.^211,212211. T. Zhuang, A. Shashurin, T. Denz, P. Vail, A.
Pancotti, and M. Keidar, " Performance Characteristics of
Micro-cathode Arc Thruster," J. Propul. Power 30, 29-34 (2014).
https://doi.org/10.2514/1.B34567212. T. Zhuang, A. Shashurin, I. I.
Beilis, and M. Keidar, " Ion velocities in a micro-cathode arc
thruster," Phys. Plasmas 19, 063501 (2012). https://doi.org/10.1063/
1.4725500 Yet, it is important to note relatively low power
efficiency of these devices when compared to Hall and ion thrusters,
primarily because of high energy losses due to metal evaporation and
ionization in nonequilibrium plasmas and nonstation discharge
transition processes. From this perspective, they may not be ideal
for missions that demand significant delta-v changes, such as orbit
rising and interplanet transitions, but provide a good fit for
precise attitude control and positioning. These operations require
high accuracy for small satellites built for the highly organized
formation flights. A greater level of miniaturization is vitally
required to fulfill the growing requirements to the accuracy of
attitude control in large satellite networks. These pressing demands
have stimulated the development of a new generation of pulsing
thrusters based on the flat (material form-factor) "printed arc
thrusters."
4. Printaed cathode arc thrusters
Printable cathode arc thrusters are propulsion devices that rely on a
pulsed or DC discharge between the two electrodes. The species to be
ionized arise as a result of electrode erosion. Once ionized, the
species are accelerated and expelled at high speed. Unlike
conventional pulsed thrusters that have a 3D geometry, printed
thrusters comprise two or more flat concentric electrodes. The
electrodes are printed using a metallic ink on a dielectic wafer,
which is typically a thin flexible polymer sheet. These thrusters can
be made exceedingly small, with a typical diameter of a few
millimeters and thickness of fractions of millimeters. They can be
produced cheaply, as they have a simple configuration. Of most
significance, however, is their ability to produce extremely small
thrust impulses for the extra-precise attitude control of the
smallest but still active satellites (e.g., picosatellites of less
than 1 kg). Further progress in the area of printable thrusters would
come from optimization of their geometry to improve the efficiency of
material ionization, and acceleration is still underexplored in flat
discharges. Another area from which advances are likely to come is in
the discovery of novel materials capable of efficiently supplying an
easily ionisable propellant to the acceleration zone and,
simultaneously, able to withstand the harsh open-space conditions
(cycling heating-cooling, ionized radiation, etc.) without the
disruption of the thin structure and material exfoliation. The group
led by Professor M. Kim from the University of Southampton, UK, had
recently produced a printed cathode arc thruster of about 5 cm size.^
88. I. Levchenko, K. Bazaka, Y. Ding, Y. Raitses, S. Mazouffre, T.
Henning, P. J. Klar, S. Shinohara, J. Schein, L. Garrigues, M. Kim,
D. Lev, F. Taccogna, R. W. Boswell, C. Charles, H. Koizumi, S. Yan,
C. Scharlemann, M. Keidar, and S. Xu, " Space micropropulsion systems
for Cubesats and small satellites: From proximate targets to
furthermost Frontiers," Appl. Phys. Rev. 5, 011104 (2018). https://
doi.org/10.1063/1.5007734
5. Electrodeless systems with rotating and complex-shape magnetic
fields
Electrodeless systems with rotating and complex-shape magnetic fields
do not involve an exchange of current between the plasma and
conductive electrodes, thus excluding power and material losses that
arise as a result of material heating, erosion, and energy spent on
work function. Although in principle highly efficient, electrodeless
systems are at the very early stages of miniaturization, with their
advancement hindered by the exceptionally complex physics of the
processes that underpin these systems. However, significant progress
has already been achieved by several teams working on helicon
thrusters (i.e., the group led by Professor S. Shinohara at the Tokyo
University of Agriculture and Technology, see their article in
Physics of Plasmas),^213213. S. Shinohara, T. Hada, T. Motomura, K.
Tanaka, T. Tanikawa, K. Toki, Y. Tanaka, and K. P. Shamrai, " 
Development of high-density helicon plasma sources and their
applications," Phys. Plasmas 16, 057104 (2009). https://doi.org/
10.1063/1.3096787 Rotamak-type systems designed by SPCS, Singapore
(see their video article in the Journal of Visualized Experiments),^
214214. J. W. M. Lim, I. Levchenko, M. W. A. B. Rohaizat, S.
Levchenko, K. Bazaka, and S. Xu, " Optimization, test and diagnostics
of miniaturized Hall thrusters," J. Vis. Exp. 144, e58466 (2019). and
radio frequency electrothermal thrusters (the "Pocket Rocket,"
designed by the Space Plasma Power and Propulsion Group at the
Australian National University, see the article in Plasma Sources
Science and Technology).^215215. C. Charles and R. W. Boswell, " 
Measurement and modelling of a radiofrequency micro-thruster," Plasma
Sources Sci. Technol. 21, 022002 (2012). https://doi.org/10.1088/
0963-0252/21/2/022002 At present, it is not clear whether these and
similar systems will eventually be scaled down to a Cubesat scale or
whether they will only ever occupy a niche reserved for the medium
and high power thrusters.
6. Electrospray thrusters
Electrospray thrusters occupy a niche between the flat printed
systems that generate ultralow thrust pulses and micropulsed
thrusters. Electrostatic voltage is applied to electrospray emitters
to accelerate liquid propellant, the latter exiting from a channel
with a small diameter. Compared to other miniaturized device
configurations, electrospray thrusters can be viewed as a relative
mature technology that is inherently miniature. Scaling these devices
down further would most probably be driven by the use of complex
nanostructures as the needles. Where currently electrospray systems
employ porous tungsten, future microfabricated emitter tips can be
made of silicon. The possibility multiplexing electrospray
microthrusters makes this technology attractive for the use of
Cubesats and other small space assets. In addition to silicon
technology, other advanced complex metamaterials coupled with
optimized device geometry may further enhance thruster efficiency and
reduce its size. The thrusters of this type have already been used in
the Laser Interferometer Space Antenna (LISA Pathfinder) project, see
the article in Acta Astronautica.^216216. C. Scharlemann, N.
Buldrini, R. Killinger, M. Jentsch, A. Polli, L. Ceruti, L. Serafini,
D. DiCara, and D. Nicolini, " Qualifciation test series of the indium
needle FEEP micro-propulsion system for LISA Pathfinder," Acta
Astronaut. 69, 822-832 (2011). https://doi.org/10.1016/
j.actaastro.2011.05.037
The aforementioned examples provide but a brief snapshot of the
current efforts by many research and engineering teams to miniaturize
various space assets to meet the growing expectations of the space
industry and, in doing so, respond to a number of global challenges.
Global information access, distributed orbital networks, and
exploration of extraterrestrial bodies for gathering vital
information and founding a solid base for their approaching
colonization would be among the prime benefits of the efficient
low-scale thrust systems.
C. Advanced space materials
Superrational distances, billions of light years of dark spiritless
space and billions of years of existence--this is our Universe. Is
interplanetary space travel just a dream, or have we finally reached
a stage where we have the capacity to develop technologies
sufficiently advanced to allow colonization of Mars, or at the very
least, extend exploration of remote planets? There are no repair
shops, no fueling, and charging stations along the way, and, for
unmanned probes, the flight path and spacecraft configuration are
controlled by the automatic equipment and remote control systems,
without any crew present on board. To survive for long time under
severe conditions in open space and on surfaces of other planets,
space assets should ideally be self-healing and highly adaptable. In
most instances, these features are impossible to attain within the
framework of traditional materials and design paradigms. To ensure
real progress in exploring the near-Earth and remote space and to
realistically approach the existing plans for Mars and Moon
colonization,^3,43. S. Do, A. Owens, K. Ho, S. Schreiner, and O.
deWeck, " An independent assessment of the technical feasibility of
the Mars One mission plan--updated analysis," Acta Astronaut. 120,
192-228 (2016). https://doi.org/10.1016/j.actaastro.2015.11.0254. I.
Levchenko, S. Xu, S. Mazouffre, M. Keidar, and K. Bazaka, " Mars
colonization: Beyond getting there," Glob. Chall. 3, 1800062 (2018).
https://doi.org/10.1002/gch2.201800062 novel dynamic, self-healing
materials should be designed to realize the next generation of
spacecraft and bring about a new generation of humans as a
multiplanetary species.^22. E. Musk, " Making humans a
multi-planetary species," New Space 5, 46-61 (2017). https://doi.org/
10.1089/space.2017.29009.emu Specifically, the ability of novel
advanced space materials to actively self-heal and self-assemble
would be considered as one of the most important technological
frontiers.
1. Is a self-healing plasma thruster possible?
However, when examining self-healing features and abilities of the
materials used in spacecraft design, we should first of all consider
the intended use and design of a specific system onboard of
spacecraft. Indeed, while the design elements of the spacecraft bus
and frame panels suffer mainly from internal cracks and similar
damage due to degradation of the bulk material, other subsystems such
as power units and control electronics would suffer from quite
different effects, such as thermal degradation, electrical
breakdowns, and electric current-induced diffusion. The critical
elements of the electric propulsion thrusters of interest here are
mainly degraded and sputtered by the effect of plasma fluxes and very
strong heat loads. These effects have been shown to cause extensive
material evaporation from the surfaces. In other words, in thrusters,
the bulk of material damage can be classified as surface-localized
damage. To effectively combat and halt these processes, novel
materials should feature self-healing surfaces and, moreover,
external processes should be organized in the thrusters to ensure
restoration of surfaces damaged by plasma and ion fluxes. Two
different approaches may be proposed for this aim, namely,
restoration of the surface structure and integrity by exploiting
strong electric fields at the damaged surface and redeposition onto
the damaged surfaces from plasma that is generated by the thruster
itself.^217,218217. O. Baranov, I. Levchenko, J. M. Bell, J. W. M.
Lim, S. Huang, L. Xu, B. Wang, D. U. B. Aussems, S. Xu, and K.
Bazaka, " From nanometre to millimetre: A range of capabilities for
plasma-enabled surface functionalization and nanostructuring," Mater.
Horiz. 5, 765-798 (2018). https://doi.org/10.1039/C8MH00326B218. O.
Baranov, K. Bazaka, H. Kersten, M. Keidar, U. Cvelbar, S. Xu, and I.
Levchenko, " Plasma under control: Advanced solutions and
perspectives for plasma flux management in material treatment and
nanosynthesis," Appl. Phys. Rev. 4, 041302 (2017). https://doi.org/
10.1063/1.5007869 It goes without saying that plasma is capable of
producing a widest spectrum of particles with sizes ranging from
nanometers through millimeters, i.e., quite suitable for various
materials and repair scenarios. Selective deposition of the repairing
material onto the damaged surface could be in principle organized by
taking advantage of the electric field at the plasma-surface
interfaces; the irregular pattern of the electric field could promote
selective deposition onto the damaged surface in such a way as to
fill the damaged features, thus rebuilding the surface and restoring
an even topography of the design elements. Conceptual experiments
have already demonstrated the possibility of such a strategy for
plasma-induced reorganization at surfaces.^219-221219. J. P. Trelles,
" Pattern formation and self-organization in plasmas interacting with
surfaces," J. Phys. D: Appl. Phys. 49, 393002 (2016). https://doi.org
/10.1088/0022-3727/49/39/393002220. J. P. Allain and A. Shetty, " 
Unraveling atomic-level self-organization at the plasma-material
interface," J. Phys. D: Appl. Phys. 50, 283002 (2017). https://
doi.org/10.1088/1361-6463/aa7506221. M. Sanduloviciu, " On the
physical basis of self-organization," J. Mod. Phys. 4, 364 (2013).
https://doi.org/10.4236/jmp.2013.43051 Moreover, electric-field
induced self-organization and ordering on the surfaces can also
stimulate the processes of self-healing and restoration by promoting
re-distribution of material on the surface.^222-224222. I. Levchenko,
K. Bazaka, M. Keidar, S. Xu, and J. Fang, " Hierarchical
multi-component inorganic metamaterials: Intrinsically driven
self-assembly at nanoscale," Adv. Mater. 30, 1702226 (2018). https://
doi.org/10.1002/adma.201702226223. O. Baranov, S. Xu, K. Ostrikov, B.
B. Wang, K. Bazaka, and I. Levchenko, " Towards universal
plasma-enabled platform for the advanced nanofabrication: Plasma
physics level approach," Rev. Mod. Plasma Phys. 2, 4 (2018). https://
doi.org/10.1007/s41614-018-0016-7224. R. Previdi, I. Levchenko, M.
Arnold, M. Gali, K. Bazaka, S. Xu, K. Ostrikov, K. Bray, D. Jin, and
J. Fang, " Plasmonic platform based on nanoporous alumina membranes:
Order control via self-assembly," J. Mater. Chem. A 7, 9565-9577
(2019). https://doi.org/10.1039/C8TA11374B
D. New paradigms and hybrid concepts
1. Laser-plasma systems
Apart from the "classical" plasma-based propulsion systems outlined
above, other concepts could be considered in the nearest future, and
among them, the "laser-plasma systems" may be of key importance (Fig.
21). It is possible to design thrust systems that take advantage of
photonic propulsion to propel spacecraft in space. These can employ
laser radiation generated by a power station based on the ground, on
a space base, or on board. The light can then be used to drive the
acceleration of a propellant, which can be a solid or a liquid.^
225,226225. L. N. Myrabo, " World record flights of beam-riding
rocket lightcraft--demonstration of "disruptive" propulsion technology
," AIAA Paper 01-3798, 2001.226. G. Bergstue, R. Fork, and P.
Reardon, " An advanced optical system for laser ablation propulsion
in space," Acta Astronaut. 96, 97-105 (2014). https://doi.org/10.1016
/j.actaastro.2013.11.021 A microthruster that uses light to ablate a
solid target is currently being developed.^227227. M. Nakano, T.
Ishikawa, and R. Wakabayashi, " Laser propulsion technology on KKS-1
microsatellite," Rev. Laser Eng. 39, 34-40 (2011). https://doi.org/
10.2184/lsj.39.34 There are several benefits to using light for
propellant acceleration. One of the major advantages lies in the
ability to physically disconnect the spacecraft and power generation
unit. Not only would this result in a lighter and more compact
spacecraft, but since the power source would not have to be
accelerated with the spacecraft, higher efficiency may be realized.
Furthermore, power generation methods that involve large or heavy
infrastructure or may present danger for the crew, e.g., a nuclear
reactor, may be used. The efficiency of the propellant would deliver
the desired specific impulse.
figure
FIG. 21. Artistic presentation of several types of photonic space
thrust platforms, where laser beams may be used to power plasma-based
thrusters. An externally generated laser beam with a significantly
higher power density than that of sunlight could be converted to
electric energy and used to accelerate working fluid and produce
thrust via plasma acceleration. Reprinted with permission from
Levchenko et al., Nat. Photonics. 12, 649 (2018). Copyright 2018,
Springer-Nature.^66. I. Levchenko, K. Bazaka, S. Mazouffre, and S.
Xu, " Prospects and physical mechanisms for photonic space propulsion
," Nat. Photonics 12, 649-657 (2018). https://doi.org/10.1038/
s41566-018-0280-7

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It may be possible to operate such ablation-type photonic thrust
systems in transverse and coaxial modes. In the former, the laser
beam reaches the target from the side^228228. C. R. Phipps, J. R.
Luke, W. Helgeson, and R. Johnson, " A ns-pulse laser microthruster,"
AIP Conf. Proc. 830, 235-246 (2006). https://doi.org/10.1063/
1.2203266 via a transparent window, whereas in the latter, the
incident flux of photons will be coaxial to the resultant reactive
jet.^229229. C. R. Phipps, " Performance test results for the
laser-powered microthruster," AIP Conf. Proc. 830, 224-234 (2006).
https://doi.org/10.1063/1.2203265 Where the transverse mode may
provide for greater flexibility with respect to thrust vector
control, the specific impulse can be effectively controlled by
altering power density at the surface of the solid target, e.g.,
through changing the pulse duration and focal radius. It may in
principle be possible to realize devices with a propellant exhaust
velocity of up to 50 000 m s^-1, given that it is possible to achieve
an ion temperature of 10 000 K in a laser focus. The plasma that is
created under the latter conditions would produce an electric field
that will further increase the exhaust velocity. Of particular
importance is the thrust-to-weight ratio that can be significantly
greater for photonic devices that use ground- or space-based sources
of power when compared to conventional electric propulsion platforms
that carry their primary power source on board of a spacecraft.^230
230. C. Phipps, W. Bohn, T. Lippert, A. Sasoh, W. Schall, and J.
Sinko, " A review of laser ablation propulsion," AIP Conf. Proc. 1278
, 710-722 (2010). https://doi.org/10.1063/1.3507164 Lightcraft is the
early realization of a photonic-powered object that demonstrates
stable flight sustained by the light from a ground-based laser.^
225,231225. L. N. Myrabo, " World record flights of beam-riding
rocket lightcraft--demonstration of "disruptive" propulsion technology
," AIAA Paper 01-3798, 2001.231. C. Phipps, M. Birkan, W. Bohn, H.-A.
Eckel, H. Horisawa, T. Lippert, M. Michaelis, Y. Rezunkov, A. Sasoh,
W. Schall, S. Scharring, and J. Sinko, " Laser-ablation propulsion,"
J. Propul. Power 26, 609-637 (2010). https://doi.org/10.2514/1.43733
Although Lightcraft employs shock waves produced in air to achieve
propulsion, the interactions between laser light and matter are
critical to the transfer of energy from the Earth to this system.
Electromagnetic systems feature a number of notable advantages when
compared to conventional systems currently used for space propulsion.
For this reason, it is imperative that we continue to pursue the
realization of highly efficient electromagnetic modes of propulsion
and continuous advancement and optimization of space propulsion
systems that are already serviceable.
In particular, the magnetically shielded Hall thrusters were proposed
for life extension and possible operation at higher voltages and in
the dual-mode configurations capable of providing low and high
specific impulses; the high power thrusters may be realized in the
nested-channel configuration. The gridded ion thrusters may be
equipped with radio frequency preionization stages to ensure higher
efficiency and power.
Among others, the PEGASES (plasma propulsion with electronegative
gases) concept is of significant interest. In this system, the
gridded ion thruster accelerates alternately positively and
negatively charged ions to provide thrust by accelerating both
positive and negative ions from the same source. This eliminates the
need for additional neutralizers (cathodes).^232232. A. Aanesland, D.
Rafalskyi, J. Bredin, P. Grondein, N. Oudini, P. Chabert, L.
Garrigues, and G. Hagelaar, " The PEGASES gridded ion-ion thruster
performance and predictions," in 33st International Electric
Propulsion Conference, The G. Washington University, USA, 6-10
October (2013), Paper No. IEPC-2013-259.
The field-emission electric propulsion (FEEP) is especially important
for Cubesats due to their ultraminiaturized form-factor. Yet, at
present, they provide very low thrust, so the search for increasing
the thrust level for larger satellites is the most actual challenge
here. Moreover, the interaction between the metal propellant of FEEP
thrusters and the satellites, especially at high power and higher
mass flow rates, is a problem that remains to be solved.
The electrospray (ionic liquid) thrusters are interesting for their
long lifespan, utilization of liquid propellant, and possibility to
cover sides of satellites if made as thin thrusters. However, they
feature low current density that should be increased to make the
electrospray systems more applicable.
Hollow cathodes intended for space propulsion applications have been
developed to operate in various propellants while producing discharge
currents from a fraction of an ampere to over 300 A. Modeling of
hollow cathodes has progressed from simple zero-dimensional particle
and energy balance models to full 2D plasma fluid codes that include
neutral dynamics, thermionic emission, electron flow and anomalous
resistivity, discharge instabilities, and life predictions. The
technology of hollow cathodes has also progressed, as shown by new
heater and heaterless designs, new thermionic emitter developments,
and active instability suppression techniques that produce cathodes
with >10 kh life. Work in these areas continues.
There is still considerable research and development in hollow
cathode physics going forward. Theoretical and experimental
investigations of the instabilities generated in the near cathode
plume region are continuing in order to predict the onset of plume
mode and energetic ion generation that lead to sputter-induce life
limitations. Techniques to fully mitigate these issues are still
needed, especially at very high discharge currents over 100 A in
order to provide the life required for deep space missions. Further
research is needed that incorporates fully consistent thermal models
with the plasma modeling to broaden the understanding of
cathode-related physics to enable the design of more power-efficient
cathodes that require less propellant gas to operate and provide
lifetimes approaching 100 kh.
One more interesting application is the use of plasma thrusters for
Spacecraft-plasma-debris removal (Fig. 22).^233233. F. Cichocki, M.
Merino, and E. Ahedo, " Spacecraft-plasma-debris interaction in an
ion beam shepherd mission," Acta Astronaut. 146, 216-227 (2018).
https://doi.org/10.1016/j.actaastro.2018.02.030 As government
agencies and private sector continue to deploy an increasingly large
number of space assets into Earth orbits, the question of space junk
and debris removal becomes fundamental to the continuous exploitation
of these orbits. Deceleration may be used to deorbit the debris and
facilitate their entry into the atmosphere. However, once the space
asset runs out of fuel, finding an external means of applying the
decelerating force is not trivial. One possible option is to use
another satellite capable of producing a sufficiently powerful plasma
beam that it can direct at the debris to decelerate it, and another
plasma beam that it can use to ensure a safe distance is maintained
between itself and the debris. For this purpose, a magnetic nozzle
plasma thruster may be well suited, as it can support bi-directional
ejection via two open exits. Laboratory tests using a space
simulation facilities have provided early confirmation that this
propulsion platform can indeed exert a deceleration force on the
debris (approximated by a target plate) while maintaining zero net
force on the thruster. Importantly, these forces can be independently
controlled by modifying the external electrical parameters,
confirming the possibility of switching between acceleration/
deceleration modes in a single propulsion device.^234234. K.
Takahashi, C. Charles, R. W. Boswell, and A. Ando, " Demonstrating a
new technology for space debris removal using a bi-directional plasma
thruster," Sci. Rep. 8, 14417 (2018). https://doi.org/10.1038/
s41598-018-32697-4
figure
FIG. 22. An open exit magnetic nozzle RF plasma thruster forms a
single electric propulsion device where control of the momentum flux
imparted onto the debris is obtained via the control of the plasma
momentum fluxes ejected at each open exit using variable external
parameters (solenoid currents and propellant gas flow rates).
Reprinted with permission from Takahashi et al., Sci. Rep. 8, 14417
(2018). Copyright 2018 Author(s), licensed under a Creative Commons
CC-BY License.

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2. Hybrid systems
Hybrid systems incorporating several different schematic solutions
may be also a very promising alternative to the existing classical
platforms.^235235. D. Ichihara, T. Uno, H. Kataoka, J. H. Jeong, A.
Iwakawa, and A. Sasoh, " Ten-Ampere-Level, Applied-Field-Dominant
Operation in Magnetoplasmadynamic Thrusters," J. Propul. Power 33,
360-369 (2017). https://doi.org/10.2514/1.B36179 There are many
options on how the already known and tested systems can be combined
into novel platform to enhance their characteristics and
capabilities; here, we outline several examples that may inform
further investigations in this field. One of the most promising
approaches could possibly combine the two major classes of electric
propulsion systems, namely, electrostatic and electromagnetic
platforms. Indeed, a series of the most recent works has demonstrated
great potential of such hybrid systems. Figure 23(a) shows the hybrid
system that has been successfully tested at the Department of
Aerospace Engineering, Nagoya University.^236236. A. Sasoh, K.
Mizutani, and A. Iwakawa, " Electrostatic/magnetic ion acceleration
through a slowly diverging magnetic nozzle between a ring anode and
an on-axis hollow cathode," AIP Adv. 7, 065204 (2017). https://
doi.org/10.1063/1.4985380 The electrostatic-magnetic hybrid system
includes a central-cathode electrostatic thruster (CC-EST) with a
centrally located hollow cathode and a ring anode that form an
electrostatic system; along with this, a diverging magnetic field has
been applied to this system with the help of externally located coils
or permanent magnetic system. Further, developments of this system
(CC-EST-1 and CC-EST02) have also been reported, proving the
viability of hybrid technologies incorporating hollow cathodes and
various external acceleration subsystems, both of the electrostatic
and electrodynamic character.^26,23526. A. Sasoh, H. Kasuga, Y.
Nakagawa, T. Matsuba, D. Ichihara, and A. Iwakawa, " 
Electrostatic-magnetic-hybrid thrust generation in central-cathode
electrostatic thruster (CC-EST)," Acta Astronaut. 152, 137-145
(2018). https://doi.org/10.1016/j.actaastro.2018.07.052235. D.
Ichihara, T. Uno, H. Kataoka, J. H. Jeong, A. Iwakawa, and A. Sasoh,
" Ten-Ampere-Level, Applied-Field-Dominant Operation in
Magnetoplasmadynamic Thrusters," J. Propul. Power 33, 360-369 (2017).
https://doi.org/10.2514/1.B36179 In hybrid systems incorporating
electrostatic acceleration stages, an important feature is additional
electromagnetic acceleration character; a unique combination of both
electrostatic and electromagnetic acceleration mechanisms would be
capable of significantly broadening the functional diversity of the
space electric propulsion systems.
figure
FIG. 23. Where do the frontiers lie? Hybrid and novel advanced
concepts. (a) Electrostatic-magnetic-hybrid thrust generation in
central-cathode electrostatic thruster (CC-EST). Reprinted wih
permission from Sasoh et al., AIP Adv. 7, 065204 (2017). Copyright
2017 Author(s), licensed under a Creative Commons CC-BY License.^236
236. A. Sasoh, K. Mizutani, and A. Iwakawa, " Electrostatic/magnetic
ion acceleration through a slowly diverging magnetic nozzle between a
ring anode and an on-axis hollow cathode," AIP Adv. 7, 065204 (2017).
https://doi.org/10.1063/1.4985380 (b) Layout of VASIMR system.
Reprinted with permission from Arefiev et al., Phys. Plasmas 11, 2942
(2004). Copyright 2004 AIP Publishing.^237237. A. V. Arefiev and B.
N. Breizman, " Theoretical components of the VASIMR plasma propulsion
concept," Phys. Plasmas 11, 2942 (2004). https://doi.org/10.1063/
1.1666328 (c) Schematics of the magnetoplasma thruster prototype of
variable Specific Impulse Magnetoplasma Rocket (VASIMR). Reprinted
with permission from Phys. Plasmas 11, 5125 (2004). Copyright 2004
AIP Publishing.^238238. R. Boswell, O. Sutherland, C. Charles, J. P.
Squire, F. R. Chang Diaz, T. W. Glover, V. T. Jacobson, D. G.
Chavers, R. D. Bengtson, E. A. Bering III, R. H. Goulding, and M.
Light, " Experimental evidence of parametric decay processes in the
variable specific impulse magnetoplasma rocket (VASIMR) helicon
plasma source," Phys. Plasmas 11, 5125 (2004). https://doi.org/
10.1063/1.1803579 The hybrid technologies incorporating hollow
cathodes and various external acceleration subsystems, both of
electrostatic and electrodynamic character, could be capable of
significant broadening the functional diversity of the space electric
propulsion systems.

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Another example of a prospective hybrid system is a Variable Specific
Impulse Magnetoplasma Rocket (VASIMR) platform that has not been
tested in space so far but demonstrates quite promising
characteristics in lab tests and theoretical studies [Figs. 23(b) and
23(c)]. This system employs three major components, namely, a helicon
plasma source, an ion cyclotron-resonance heating section, and a
magnetic nozzle. This system is particularly promising now, when the
need in thrusters for fast, convenient Earth-Mars flights has
appeared. Indeed, the VASIMR concept has been proposed for
interplanetary missions, due to its unique capabilities of operating
at different specific impulses, to power the cruise phase of the
flight when high impulse and lower thrust are required, and
maneuvering phases near the planets when higher thrust levels are
needed. Moreover, the VASIMR system is also very promising in terms
of long operation life, since it uses the radio frequency radiation
to ionize and accelerate the propellant. Being an intrinsically
electrode-less system, VASIMR does not incorporate any electrodes to
sustain gas ionization and plasma acceleration, and so its
operational lifetime is not limited by erosion of any critical parts.
While first proposed in the early 1980s, this concept is still at the
relatively early stages of development, due to the two main reasons:
absence of efficient power sources of the required (relatively high)
power level and absence of the realistic missions to drive. Now, when
the Mars and Moon colonization is at the top of the agenda, further
development and practical realization of the hybrid system such as
VASIMR are expected to be at the frontiers of the space electric
propulsion systems.
3. Complex optical systems for ion thrusters
Along with other types, gridded ion thrusters still attract
significant interest, especially for the missions that require very
high specific impulse. However, the intrinsic problem of the gridded
ion thrusters, the low ion flux (and hence thrust) surface density,
still needs to be addressed. The complex multigrid system is one of
the recently emerged promising techniques that could in principle
drastically enhance the surface thrust density without compromising
their specific impulse and grid sputtering-determined service life.^
17,23917. C. Charles, " Plasmas for spacecraft propulsion," J. Phys.
D: Appl. Phys. 42, 163001 (2009). https://doi.org/10.1088/0022-3727/
42/16/163001239. C. Bramanti, R. Walker, O. Sutherland, R. Boswell,
C. Charles, D. Fearn, J. G. Del Amo, and M. Orlandi, " The innovative
dual-stage 4-grid ion thruster concept--Theory and experimental
results," AIAA Paper AC-06-C4.4.7 (2012).
While the traditional gridded ion systems comprise usually two grids
that extract and focus the ion flux from plasma and accelerate it, in
the three-gridded system [Fig. 24(a)], the third grid is a
decelerating grid. As a result, much higher potential may be applied
to the second (accelerating) grid "to ensure much higher current and
hence thrust density Newton per meter square." The third
(decelerating) grid is used to decelerate the ion flux and thus not
to operate on too high specific impulse, which is an optimized
mission-dependent parameter.^2525. R. C. Koppel, " Optimal specific
impulse of electric propulsion," Proceedings of the 2nd European
Spacecraft Propulation Conference, Noordwijk, the Netherlands, edited
by M. Perry, 27-29 May 1997, pp. 131-139. In this system, the first
(screen) grid ensured better collimation of the extracted ion flux
and thus significantly reduces the sputtering of the acceleration
grot, which is the principal life-limiting factor in ion thrusters.^
174174. M. Sangregorio, K. Xie, N. Wang, N. Guo, and Z. Zhang, " Ion
engine grids: Function, main parameters, issues, configurations,
geometries, materials and fabrication methods," Chin. J. Aeronaut. 31
, 1635-1649 (2018). https://doi.org/10.1016/j.cja.2018.06.005 To
further enhance the process, decrease the gird sputtering, and
mainly, to enhance the thrust surface density, a novel 4-grid system
has recently been proposed and successfully tested [Fig. 24(b)].^239
239. C. Bramanti, R. Walker, O. Sutherland, R. Boswell, C. Charles,
D. Fearn, J. G. Del Amo, and M. Orlandi, " The innovative dual-stage
4-grid ion thruster concept--Theory and experimental results," AIAA
Paper AC-06-C4.4.7 (2012).
figure
FIG. 24. Perspective concepts for the gridded ion thrusters: (a)
triple grid and (b) four-grid configurations. The most advanced
4-grid system significantly reduces the grid sputtering and allows
for up to 80 kV acceleration potential, which results in much higher
thrust density.

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The four-grid ion thrusters are in fact a dual-stage system where the
processes of ion flux extraction and acceleration are decoupled, in
contrast to the traditional three-grid systems where flux extraction
and acceleration proceed simultaneously, with the maximum ion
potential limited to about 5 kV. In the four-grid ion thrusters, the
first stage efficiently extracts ions from the plasma by using the
two front grids, while a longer second stage formed by the 3rd and
4th grids accelerates ions to much higher potentials reaching 80 kV.
In summary, the recent successes in the development of plasma-based
space propulsion systems discussed in this article suggest that this
family of propulsion platforms is bound to play an important, perhaps
even crucial, role in the advancement of our capabilities in space
exploration, exploitation, and, eventually, colonization of other
celestial bodies.

ACKNOWLEDGMENTS

This work was supported in part by the following funds and
organizations: OSTIn-SRP/EDB through National Research Foundation and
in part by MoE AcRF (No. Rp6/16 Xs), Singapore. I.L. acknowledges the
support from the School of Chemistry, Physics and Mechanical
Engineering, Science and Engineering Faculty, Queensland University
of Technology. The authors express special thanks to L. Xu, M. Lim,
S. Huang, and the entire PSAC/SPCS for their help K.B. acknowledges
the support from the Australian Research Council.

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