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Cryogenics / Electronics / Quantum Computing / Semiconductor / SiGe /
SOI / Space / Technology

Can Electronics made of COTS components work at cryogenic
temperatures?

September 24, 2020 - by electron_one - Leave a Comment
[gif][electronics-survive-cryogenic-temperatures-new-x650]

Space travel is so attractive to us while it is so challenging to
scientists and engineers. For long time since 1957 when the first
space mission was launched, designing device that can survive the
extreme conditions in the space has been the priority of any space
exploration program. The on-board electronics for space applications
presents special requirements for the materials, packaging,
components, and protection. The specially designed electronics for
space systems, such as the electrical power management and control
systems that are capable of all designated functionalities in the
ultra-low temperature environments offers lots of advantages over the
current systems housed in the "warm box" that utilizes radioisotope
heating units to keep the on-board electronic devices at a constant
20 C. Electronic devices that are capable of working at cryogenic
temperature can overcome the harsh environment of deep space, shrink
the size, reduce the overall weight, lower the power consumption and
shorten the development time. From the aspect of performance, power
electronics can have higher efficiency at lower temperature than room
temperature, which in turn results in optimal device behaviors and
fault tolerance in the electrical and thermal properties of the
semiconductor and dielectric materials at low temperatures. The Low
Temperature Electronics Program at the NASA Glenn Research Center,
Cleveland, OH, has conducted a research on devices and systems for
planetary exploration and their efficient and reliable performance
down to cryogenic temperatures as low as -243degC or 30K. Their
research involves characterizing the COTS (Commercial-Off-The-Shelf)
components and some developed passive and active devices.

Space environment is hostile to not only human but also electronics.
The spaceships must be designed to withstand the ultra-low
temperature, vibration at various frequencies, high-g shock, and
cosmic radiation. For the temperature, it varies within a much wider
range than the operating temperature range for most electronic
components have been specified, from -55 to +125degC. For example, the
surface temperature pf the Moon ranges from -200degC to +200degC. The
following picture shows the temperature contour map of the south pole
of Moon.

[gif][The-contour-map-of-temperatures-of-the-PSRs-Permanently-Shad]
Data was acquisitioned from the LRO (Lunar Reconnaissance Orbiter)
Diviner Lunar Radiometer Experiment.

Some spots of the map show extremely cold temperature. That is
because the bottom of the craters in the region of south pole are
never exposed to sunlight. In contrast, some peaks and crater rims
are exposed to sunlight over 80% of the time, so the temperature is
very high on those spots. The LRO (Lunar Reconnaissance Orbiter)
on-board Diviner instrument has reported extreme temperatures as low
as -238degC (-397degF) within the PSRs (Permanently Shadowed Regions),
which is even colder than the surface temperature of Pluto.

[gif][The-temperatures-on-the-planets-of-solar-system]Table 1. The
temperatures on the planets of solar system

Not only the space exploration presents low temperature challenge to
classical electronic devices, but also the modern quantum computing
technology requires the core systems to work at cryogenic
temperatures. There are many reasons for why we must understand how
electronic components and the circuits consist of these components
work at such low temperatures. Cryogenic temperature has huge impact
to the electronic components, such as the life span and performance.
The specially designed COTS components for the specified operating
temperature range must be used. It has been reported that at cold
temperatures, many characteristics of COTS components are improved as
many device parameters saturate below 50 K demonstrating predictable
excellent performance. For bulk and SOI Si CMOS devices, the key
device metrics, the I[DS_Sat], g[m], u[eff], S and I[off], etc.
improve at low temperature, while VT and hot carrier reliability
degrade at cold temperature. The threshold voltage increases at low
temperature is because of the increased Fermi potential and expanded
depletion region. For bulk and SOI SiGe HBT (Heterojunction Bipolar
Transistor) devices, the b, V[A], g[m], f[T], f[max], NF[min] improve
while b at low currents degrades. (John D. Cressler) In contrast to
early SiGe HBTs, advanced SiGe HBTs show excellent potential for
cryogenic operations as reported achievements of a fT at 710 GHz and
a fmax at 618 GHz both at 4 K, which accounts for a 70% improvement
over the reported records at room temperature. Compared to Si based
BJTs based on early technology, the advanced SiGe technology has the
intrinsic resistance to ionizing radiation due to the fabrication
process and the high speed of SiGe HBTs under cooled temperature due
to the bandgap engineering.

In another study of characterizing 0.18 um CMOS transistors over
temperature from 300 K to 4.2 K was reported. In this study, the
drain current ID increased with decreasing temperature due to the
increased carrier mobility. It also shows the threshold voltage VT
increased at low temperature for both NMOS and PMOS transistors. At
lower temperature, the carrier mobility is greatly enhanced due to
the reduced carrier scattering caused by lattice thermal vibrations.

[gif]
[IDS-VGS-and-IDS-VDS-of-thin-oxide-NMOS-at-different-temperatures-varying-from-298K-to-]
IDS-VGS and IDS-VDS of thin-oxide NMOS at different temperatures
varying from 298K to 4.2K. W-L ratio in um[gif][Threshold-voltage-vs]
Variations and fitting curves of extracted threshold voltage at zero
substrate bias for different temperatures[gif]
[Measured-minimum-CML-ring-oscillator-gate-delay-as-a-function]SiGe
HBT CML Ring Oscillator Gate Delay Vs. Temperature

The above plot shows the Measured minimum CML ring oscillator gate
delay as a function of chuck temperature. The measurement was
achieved on a Lakeshore CPX-HF cryogenic probe station with a
temperature sweep from 4.5 K to 294 K. It shows the gate delay of the
CML ring oscillator is 2.73 ps at room temperature and the shortest
delay is 2.31 ps at 25 K. The improvement is about 15.4%.

[gif][Drain-to-source-on-resistance-for-SOI-and-standard-MOSFET-d]
Drain-to-source on-resistance for SOI and standard MOSFET devices vs.
temperature

The above plot shows the drain-to-source on-state resistance (R[DS
(on)]) versus temperature for the SOI (Silicon-on-Insulator) MOSFET
and the standard MOSFET. The two devices have shown similar behavior
in the R[DS(on) ]dependence on temperature. The lowest on-state
resistance was recorded at about -170degC and it is found that the
on-state resistance tends to increase with further decreasing
temperature after -170degC.

[gif][Current-gain-as-a-function-of-collector-current-for-temperatu]
Current gain as a function of collector current for temperature down
to 16K for the transistor shown in the figure below (J.D.Cressler)
[gif]
[Current-voltage-characteristics-of-an-emitter-cap-SiGe-HBT-at-3]
Current-voltage characteristics of an emitter-cap SiGe HBT at 300K,
77K and 16K. (J.D. Cressler)

Quantum computing is one of the most exciting technological
breakthroughs. The two theoretical building blocks of quantum
computing are both taken from quantum mechanics, superposition and
quantum entanglement. The core element of a quantum computer is
called qubits. At least a few thousands and up to several millions of
qubits are required for quantum computing and all of these qubits
work at deep cryogenic temperatures.

[gif][D]D. Manger et. al., Integration of SiGe HBT with fT = 305 GHz,
fmax = 537 GHz in 130nm and 90nm CMOS[gif][SiGe-HBT-operating-at-4]
Chakraborty, P.S., et al., "A 0.8 THz SiGe HBT operating at 4.3 K",
Electron Device Letters, IEEE, Vol.35, pp. 151, 153, Feb. 2014[gif]
[SiGe-HBT-shows-very-high-speed-at-very-low-power-John-D]SiGe
Exhibits Very High Speed at Very Low Power John D. Cressler

According to John D. Cressler, bulk Si CMOS devices work well at
temperatures down to 43K and below. The physical mechanisms of the
band-gap engineering are enhanced at cryogenic temperatures.

The improvement of SiGe HBTs performance at cryogenic temperatures is
great news. The SET quantum computing readout has several challenges
to overcome. The SET devices are highly sensitive to the environment
and have low output signals in the 100 pA range. The dry dilution
refrigerators have low thermal budgets and imposes serious EMI
problems. Also, the large number of leads to and from the device
sitting in the fridge are so long that present highly resistive and
capacitive characteristics. For long time, silicon JFETs have been
the only option for the low frequency and high-impedance readout
electronics with very low noise performance (about 1nV/Hz^1/2). But
these devices cannot operate below 100 K. Therefore, the JFET readout
circuits must be separated from the cooled electronics and require
long cables to connect them. As the advanced SiGe HBTs are excellent
for cryogenic temperature operations, they are considered viable
technology for making the amplifiers for SET (Single-Electron
Transistor) silicon quantum computing readout. There are several
analog amplifiers based on SiGe HBTs have been designed and two
topologies have been commonly used now. The SiGe HBTs can provide the
best gain vs. power characteristics of any solid-state devices at the
working temperature. The design f the amplifiers have used COTS
discrete components.

The study conducted by T. Chen and J Cressler et. Al., "CMOS
reliability issues for emerging cryogenic Lunar electronics
applications" for lunar designing the complex suite of electronics
systems used in sensing, actuation, and control of robotic systems
provided insight to how reliable the full suite of mixed-signal
circuit building blocks can be within operating over such extremely
wide temperature range.

[gif][CMOS-reliability-issues-for-emerging-cryogenic-Lunar-el]ID vs.
VG for nFET and pFET devices at different temperatures.[gif]
[CMOS-reliability-issues-for-emerging-cryogenic-Lunar-elec]ID versus
VD for nFET and pFET devices at different temperatures.

The above two plots demonstrate the typical I-V characteristics of
the CMOS deices at temperatures from 43 K to 300 K, with VDS = 50 mV
and VGS = 3.3V respectively. At lower temperatures, the current drive
capability increases significantly with the same bias conditions.
This indicates the performance of the device is greatly improved at
lower temperature.

[gif][CMOS-reliability-issues-for-emerging-cryogenic-Lunar-electro]
The inferred lifetime as a function of bias condition for an nFET at
82, 200, and 300 K.

Si CMOS devices present enhanced performance at cryogenic
temperatures. At the same time, they achieve the excellent
performance at the cost of shorter device reliability lifetime. The
degradation of device lifetime can be compensated by using CMOS with
longer channel transistors because the long channel length can
suppress the hot carrier reliability degradation. The drawback of
long channel is the lower W/L ratio that causes lower circuit speed
due to the smaller output current driving capability. Therefore,
trade-offs must be made between the circuit speed and reliability.

 

Reference

 1. Richard L. Patterson et al., "Electronic Components for Use in
    Extreme Temperature Aerospace Applications", 12th International
    Components for Military and Space Electronics Conference (CMSE
    08), San Diego, California, February 11-14, 2008
 2. Del Castillo et al., "Electronic packaging and passive devices
    for low temperature space applications," 2018 IEEE Aerospace
    Conference, Big Sky, MT, 2018, pp. 1-13, doi: 10.1109/
    AERO.2018.8396521.
 3. Cressler. Operation of SiGe bipolar technology at cryogenic
    temperatures. Journal de Physique IVColloque, 1994, 04 (C6),
    pp.C6-101-C6-110. 10.1051/jp4:1994616. jpa-00253110
 4. Yuan and J. Cressler et. Al., "SiGe HBT CML Ring Oscillator With
    2.3-ps Gate Delay at Cryogenic Temperatures", IEEE Transactions
    on Electron Devices, Vol. 57, NO. 5, May 2010
 5. Chen and J Cressler et. Al., "CMOS reliability issues for
    emerging cryogenic Lunar electronics applications", Solid-State
    Electronics 50 (2006) 959-963
 6. Manger et al., "Integration of SiGe HBT with fT=305 GHz, fmax=537
    GHz in 130nm and 90nm CMOS," 2018 IEEE BiCMOS and Compound
    Semiconductor Integrated Circuits and Technology Symposium
    (BCICTS), San Diego, CA, 2018, pp. 76-79.
 7. Chakraborty, P.S., et al., "A 0.8 THz SiGe HBT operating at 4.3
    K", Electron Device Letters, IEEE, Vol.35, pp. 151, 153, Feb.
    2014
 8. Luo, Chao, et al. "MOSFET characterization and modeling at
    cryogenic temperatures." Cryogenics 98 (2019): 12-17.
 9. R.L. Patterson, A. Hammond and M. Elbuluk, "Assessment of
    electronics for cryogenic space exploration missions", Cryogenics
    46 (2006) 231-236

 

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