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Hurried Thoughts: You're Wrong About Tidal-Locking

[Screenshot]
Space Engine

I've already talked about tidal-locked planets at length in the past
(several times), and there won't be much new here for my regular
readers, I just figured it'd be nice to have a single relatively
short place to address the most common myths about tidal-locked
planets, and particularly their climate, for easy reference.
 
The very short version is that the popular perception of tidal-locked
planets--hostile worlds split between a burning desert on the lit
hemisphere, ice on the dark side, and, at best, a thin "twilight
strip" of habitable temperatures in between, wracked by gale-force
winds--is not a strictly impossible scenario in all its particulars,
but our current best climate models^1 predict (and have^2 for quite
some time now) that tidal-locked planets in the habitable zone with
Earth-like atmospheres and quantities of surface water can more
typically expect far more hospitable conditions^3, with comfortable
temperatures and moderate prevailing winds across the lit hemisphere;
that the hottest part of the planet will usually actually be the
wettest^4; and that this habitable climate state may actually be more
stable^5 in some ways than that of a planet more like our own.
 
For a more detailed explanation, let's back up a bit and set the
scene. Tidal-locking describes a phenomenon whereby the tidal
influence of a star on a planet (or between a planet and moon) causes
the planet's rotation to slow until one side of the planet faces
permanently towards the star, and the opposite side faces away.
Because the planet still orbits in a loop around the star, this
requires that it also rotates around once on its axis to keep that
star-side face pointed to the star, so this is also sometimes called
a 1:1 spin-orbit resonance; for every 1 orbit, the planet spins
around exactly once. The tidal influence of the star helps ensure
this exact timing, hence the "locking" aspect. There are other
spin-orbit resonances that tidal forces might lock a planet into,
like the 3:2 spin-orbit resonance of Mercury (the planet spins 3
times for every 2 orbits), but whether these planets should also be
called "tidal-locked" varies between sources; in colloquial usage,
"tidal-locking" is used almost exclusively to refer to the 1:1
resonance.

[Tidal_locking_of_the_Moon_with_the_Earth]
Rotation of a tidal-locked moon (left), as opposed to a truly
nonrotating body (right). Stigmatella aurantiaca, Wikimedia

The strength of tidal forces is strongly dependent on the distance
between the planet and star. Smaller red dwarf stars that are
substantially dimmer than our sun have habitable zones that are
correspondingly much closer to the star, so any habitable-zone
planets of these stars are much more likely to be tidal-locked. These
are by far the most common type of star in the universe, accounting
for over 3/4 of the total number, so the habitability of tidal-locked
planets is a major factor in the prevalence in habitability in the
cosmos generally.
 
Unsurprisingly, keeping one side of the planet pointed at the star
has a profound effect on how light from the star--and thus heat--is
spread over the planet's surface. On Earth, a flat surface directly
facing the sun (with no obstructions and ignoring filtering by the
atmosphere) receives about 1360 Watts per square meter (W/m^2) of
light. But Earth's rotation and axial tilt spread out this light,
such that the average light any single part of the surface receives
across the whole year (averaging together summer, winter, day, and
night) varies between a bit over 400 W/m^2 near the equator and under
180 W/m^2 at the poles (subtracting out the light reflected away by
the surface and atmosphere leaves about 2/3 of that light on average
being actually absorbed as heat).
 
On a tidal-locked world in the same orbit, the substellar point in
the middle of the daylight side, which faces most directly towards
the star, would get that full 1360 W/m^2 of light continuously. The
heating would decline towards the edge of the dayside, falling to 0 W
/m^2 at the terminator, the line dividing the day and night
hemispheres; over 2/3 of the dayside hemisphere's area would receive
more light than the average for Earth's equator. The entire nightside
receives no light from the star at all, save perhaps some meager
twilight at the edges refracting through the atmosphere.

[insol]
Average insolation across the surface of Earth (left) and a
tidal-locked planet in the same orbit (right)

It's understandable, then, that when the prospect of tidal-locked
planets was first being considered^6, such extreme contrasts in
lighting and heating were expected to be accompanied by an extreme
climate, split between a scorching hot dayside and bitter cold
nightside. Perhaps somewhere in between, near the terminator, there
should be at least a thin strip of more hospitable temperatures, but
that didn't guarantee habitability either. A common concern^7 was
that any water on the planet's surface and perhaps even CO^2 would
become trapped as ice on the nightside, leaving the dayside bone dry
and even hotter for lack of the moderating influence of water. In the
worst scenario, sequestration of ices on the nightside and
heat-driven escape of atmospheric gasses to space on the dayside
might remove such a planet's atmosphere entirely.

Even those who imagined a habitable strip imagined it dimly lit,
being so close to the terminator, and wracked by vicious winds; the
planet's strong temperature contrast would create a powerful
convection cell, with air rising on the dayside, moving at high
altitude to the nightside, and then descending and shooting back
towards the dayside close to the surface; prospects for complex life
in this constantly buffeted twilight strip would be, well, dim.

[299515_2_En_5_Fig6_HTML]
A cross-section through the atmosphere of a tidal-locked planet,
showing air circulation from the center of the dayside to the
nightside, with the terminator in the center; the "temperature
inversion" shows a portion of the lower atmosphere where temperature
rises with altitude, rather than falling. Stevenson 2019^8

This picture of tidal-locked planets as marginally habitable at best
but more likely prone to complete collapse into dry, sterile, perhaps
even airless worlds prevailed well into the 1990s^9, but as computing
technology improved and we finally gained some capability to simulate
the climates of such worlds in detail, which painted a far different
picture^2.

As it turns out, even an atmosphere substantially thinner than
Earth's could distribute enough heat to the nightside to prevent
atmospheric freeze-out, and a more Earth-like atmosphere could keep
temperatures globally within about the same range^10 we experience on
Earth. Water, too, can easily avoid^11 becoming completely trapped on
the nightside, and global oceans could then help distribute heat even
more evenly^12 across the surface.

In fact, in some circumstances, tidal-locking might even make a
habitable climate more stable. Near the inner edge of the habitable
zone, where the sun's light is more intense, the slow rotation and
global convection may allow for warm planets to develop a permanent
cloud formation that reflects away much of the star's light, keeping
temperatures moderate even in orbits^5 where a planet with Earth-like
rotation would boil from runaway greenhouse warming. At the habitable
zone's outer edge, this cooling effect would be weaker, and the sharp
gradient in heating from the star on the dayside would help prevent^
13 runaway cooling and ice formation of the sort that may have caused
Earth to freeze over completely in the past.

So, let's take a quick look at what modern modelling predicts the
actual climate of a tidal-locked planet with otherwise Earth-like
properties should look like. Temperatures across the dayside^3 could
easily vary by less than 30 degC, and the nightside would tend to be
even more uniform. Ice could still cover much of the nightside, but
it needn't stop exactly at the terminator; it could extend well into
the dayside while still leaving a substantial warm region, it could
be restricted only to some nightside pockets, or the nightside could
even thaw out completely^12. Ice cover on Earth has varied
considerably over its history through warmer and cooler climates, and
much the same would be true here.

[apjaa9f1ff7_lr]
Modelled surface temperature and prevailing winds (key shows 5 m/s)
of all-ocean tidal-locked planets with a range of indicated orbital
periods, appropriate to the habitable zone of stars with the
indicated effective temperatures. Haqq-Misra et al. 2018^3

For most cases, near-surface winds would indeed tend to converge on
the center of the dayside, but in speed and strength would typically
be no worse than a stiff breeze, comparable to the trade winds in our
tropics. Planets orbiting the very smallest stars, with short orbital
periods of under 20 days, might have more complex patterns, but I'll
point you elsewhere for that discussion.

[Screenshot]
Precipitation in a climate model of Proxima b with a
nitrogen-dominated atmosphere; the black line indicates the limit of
freezing temperatures in this model. Boutle et al. 2018^4

Conversely to the image of a dayside desert, the warmest part of the
dayside, near the center, will actually tend to be the wettest^4.
Those converging winds would pull in moisture from across the planet,
and the rising convection would encourage frequent widespread rain.
Though some climate models briefly predicted a single permanent
cyclone in the center of the dayside, it now seems more likely^14 to
be a less organized mass of stormy and rainy weather, with frequent
cloud cover but some prospect for occasional breaks. Farther from the
center of the dayside, rain would taper off, but the unusual
atmospheric structure (cool winds towards the dayside near the
surface, hot winds towards the nightside at high altitude) would
encourage frequent fog.

Ocean currents could shift around heat considerably: on a planet with
no continents, they'd tend to carry heat east, north and south of the
center of the dayside, such that rather than the typically expected
"eyeball" pattern of a circular region of open ocean surrounded by
ice, you might expect^15 more of a lobster shape extending onto the
nightside. This tendency may vary depending on orbital period,
though, and the presence of landmasses blocking free flow of currents
could weaken their overall influence.

[001aa0c1c3a1142f655023]
Modelled ice cover (left) and surface temperature (right) of a
tidal-locked planet without (top) and with (bottom) fully modelled
ocean currents. Peking University^15

Various additional factors could influence the climate in other ways,
but I've discussed that all in detail elsewhere.

Exactly why the old image of inhospitable tidal-locked worlds has
persisted this long, well after the scientific community has moved
past it^16, I couldn't say, though it certainly doesn't help when
even recent high-budget media claiming scientific accuracy repeats
the old myths. A planet of stark climate extremes is admittedly a
fairly compelling image, capturing the imagination of speculative
authors for over a century now, but a more hospitable world with vast
regions of tropical climate under eternal sunshine have their own
potential as well. 

But if you do like the concept of a habitable twilight strip between
hemispheres of desert and ice, don't despair; though we shouldn't
view this as the default climate of tidal-locked worlds, but it can
still be achieved in the right circumstances. A lower total volume of
surface water, larger nightside continents, and lower geothermal heat
will all encourage^11 trapping of water in nightside ice, potentially
allowing for drying out of the dayside. A dryer dayside and
optionally a thinner atmosphere will weaken distribution of heat,
allowing the center of the dayside to become hotter while still
allowing the nightside glaciers to spread to the terminator (though
they might not reach it evenly on all sides; expect them to more
reliably appear to the dayside's western edge). Meltwater from these
glaciers could feed into^17 a fairly broad habitable strip;
evaporated water would be carried by winds into the dayside, but so
long as the overall supply isn't too high, too little would
accumulate there to cause rain and would instead return with
high-atmosphere winds to snow down on the nightside glaciers--and the
habitable region might see some sporadic rainfall or fog as well
(there could also be slightly wetter climates where only a small
region in the center of the dayside receives rain, separated from the
glacial meltwater region by vast deserts). Winds over this habitable
strip would probably be stiffer than for the more moderate climate
state, but still not relentless gales.

[tidallock]
Beau.TheConsortium, Rare Earth Wiki
 
That about covers the main issues I wanted to cover today, but while
I'm here, I might as well go over a few other common myths and
misunderstandings regarding tidal-locked planets (and other bodies)
as well.

Tidal-Locked Moons

Just as a planet can tidal-lock to its star, a moon can tidal-lock to
its planet. Indeed, because tidal forces scale strongly with distance
and moon-planet distances are generally far smaller than planet-star
distances, almost all moons in the solar system are tidal-locked (the
few known exceptions, like Hyperion, are due to the influence of a
much larger neighboring moon causing chaotic rotation), and we can
probably expect this to be the norm for other star systems as well.

But tidal-locking of a moon to its planet means that it points one
face to that planet and so rotates once for each orbit of the planet.
Relative to the star, the moon thus spins around about once per orbit
of the planet, and so should experience a regular day and night cycle
in about that time (because the planet is moving around the star as
the moon orbits the planet, the moon needs to complete either
slightly more or slightly less--depending on the orientation of the
orbits--than one full orbit to rotate back around to face the star
again; our moon, for example, completes an orbit every 27.3 Earth
days, but requires 29.5 Earth days for one of its days).
Tidal-locking to the planet can have interesting implications for the
day-night cycle of the planet-facing side of the moon due to
potential eclipses by day and reflected light from the planet by
night, but in general the climate should resemble that of a planet
with equivalently long days rather than that of a tidal-locked planet
(because many moons have quite long orbital periods, these climates
might still be quite different from Earth's).

Tidal-locking of a moon to the planet's star rather than the planet
is, so far as I can tell, not possible. The physics governing whether
a moon can be kept in orbit of a planet at all (i.e., the Hill radius
) and those governing the strength of tidal forces are fundamentally
related such that any moon in any stable orbit of a planet must
necessarily experience stronger tidal forces from the planet than
from the star. The star might still have some influence on the moon's
motion, but the balance of forces should always drive the moon's
rotation towards locking with its motion around the planet and not
the star.

I've occasionally heard it proposed that a moon might have an orbit
as long as its planet's year, such that it can be simultaneously
tidal-locked to both planet and star, but this doesn't work out
either; again, the physics works out such that no moon can have an
orbital period longer than about 58% the length of the planet's year,
and realistically we'd expect most to have orbits limited to about 1/
5 the length of the year. There is a point directly between the
planet and star (the L1 Lagrange point) where their gravitational
influence balances out such that a body can remain temporarily locked
between the two, following the planet's orbit, but it's unstable,
like a pencil balanced on its tip; any small perturbation will nudge
the body away, such that it eventually moves off into another orbit,
either of the planet or star.

Incidentally, a planet can also be tidal-locked to its moon, facing
one side towards it as it orbits around the planet. Whether or not
the balance of tidal forces favors this is more variable, depending
on the particulars of the relative masses and distances of the
objects involved (and in some cases^18 it may change over the
planet's lifetime). If it does happen, much of what is true for the
surface climate and conditions of a tidal-locked moon are true of
this sort of planet as well. We can also generally expect that the
moon is already tidal-locked to the planet at this point, such that
they're mutually tidal-locked, permanently facing each other, as is
the case for Pluto and Charon.

[Pluto-Charon_system-new]
Motion of Pluto and Charon. Tomruen, Wikimedia

Polar Orientation

A common exchange I see online is one person asking what might happen
if a planet had one of its poles pointed towards its star, and
another person responding that this is equivalent to tidal-locking.
In a very abstract and conceptual sense this is a reasonable
response, in that tidal-locking is a realistic case for the idea of
having a part of a planet permanently facing the star, but in the
strictest sense it's not true; a tidal-locked planet still rotates,
and so still has poles, which should usually be somewhere along the
terminator, facing at right angles to the star rather than towards
it.

[planet]

Fair enough, but I sometimes also hear it proposed that perhaps a
planet could actually keep one of its poles pointed towards the star
if there was some secondary rotation turning the planet in addition
to its main rotation around its poles. In isolation, this simply
isn't geometrically possible; objects in 3-dimensional space can only
ever rotate around one axis at a time. There would need to be some
outside force continuously acting on the planet to alter its rotation
to allow this to happen. Earth does experience some precession
--continuous alteration of its rotational axis--due to the influence of
the other planets, and this is partially responsible for our cycle of
cooler glacial periods and warmer interglacials (as shifts in axial
tilt alter the amount of heating the polar regions get). But this is
a minor shift over thousands of years. To have one of the poles kept
pointed directly at the star at all times would, in terms of momentum
change and energy required, be the equivalent of of stopping Earth's
rotation completely, starting it at the same rate in the opposite
direction, stopping the rotation again, and restarting the initial
rotation every single orbit.

Earth has a total of 2.14 * 10^29 J of energy bound up in its
rotation; for a planet with similar properties and rotation, this
twice-over stopping and starting would require 4 times this amount of
energy, 8.56 * 10^29 J, every orbit. Assuming a year as long as
Earth's, that's a continuous power input of 2.71 * 10^22 W. The total
power of sunlight striking Earth (before even accounting for what's
promptly reflected away) is only 1.74 * 10^17 W. Thus, even assuming
there was some outside influence capable of providing that much power
in that specific way, if even a tiny portion of that energy was
ultimately released as heat (and really we wouldn't expect it to be
an efficient process at all), it would be plenty sufficient to push
the climate far past the bounds of habitability and roast the
surface, perhaps even melting the planet entirely.

Setting that scenario aside, a planet that has one of its poles
facing towards the sun at one point of the year and then continues on
its orbit with a constant rotational axis--pointing each pole towards
the sun in turn at opposite seasons--is a possibility (Uranus is close
to this orientation) and has its own intriguing implications for the
surface climate.

A tidal-locked planet also doesn't need to have its poles pointed at
exact right angles from the star at all times. Usually we would
expect that, because the same tidal forces that cause tidal-locking
also reduce axial tilt, a tidal-locked planet should have no tilt,
but the influence of multiple other planets or stars might lock one^
19 into a "Cassini state" with some constant effective tilt relative
to its orbit. In this case, the star would seem to shift north and
then back south in the sky over the course of an orbit, and the
terminator would shift as well, allowing for parts of the planet to
have periods of day and night. Orbital eccentricity can similarly^20
shift the terminator around over the course of the planet's orbit,
with the combined effect of shifting orientation relative to the sun
called libration.

Tidal-Locking Limits

As mentioned, tidal-locking is expected to be more common in the
habitable zones of smaller stars, because of how much stronger tidal
forces should be in the closer habitable zones of these stars.
Because of doubts about the habitability of tidal-locked planets--
which, even with better and more encouraging climate modelling, still
cannot be entirely dismissed without empirical evidence--researchers
investigating the limits of habitability around other stars have
often found it prudent to indicate which stars are likely to have
mostly tidal-locked planets. This is why you'll often see charts of
the habitable zone marked with a line indicated as a "tidal-locking
limit" or something similar.

[The-habitable-zone-for-various-types-of-stars-The-dashed]
A typical habitable zone chart (based on Kasting et al. 1993^21)
showing a "Tidal lock radius".

This is a convenient way to make the implications of these charts
readable both for those skeptical and optimistic about the prospects
for habitable tidal-locked planets, but I think non-researchers
sometimes misunderstand that line as an absolute limit; all planets
on one side of the line must be tidal-locked and all those on the
other side can never be tidal-locked.

In reality, whether or not a particular planet becomes tidal-locked
depends on a number of factors beyond just distance from the star.
First off, tidal-locking takes time; usually these charts assume an
age of 4.5 billion years, presuming that we're interested in
habitable worlds with intelligent life and that might take about as
long as it did on Earth. But depending on why you're interested in
tidal-locking, you might be considering much younger or older
planets.
 
[tide1]
Tidal-locking limits at different ages ("byr" indicates planet age in
billions of years) for Earth-like planets (dissipation factor of 100)
with 12-hour initial days. Dark green indicates the conventional
habitable zone, light green is a very optimistic habitable zone
allowing for very low surface water^22 near the star or up to 50%
atmospheric hydrogen^23 far from the star.

The time tidal-locking takes also depends strongly on the initial
rotation rate of the planet after it has formed; usually something
like 12-13 hour days are assumed for the purpose of drawing these
limits in habitable zone diagrams (I'm not totally sure why,
presumably based on some model of Earth's rotational evolution), but
in reality it could vary greatly depending on random factors like the
last few large impacts during formation. A planet might just happen
to form with very slow rotation close to the synchronous rate, so in
principle there's no strict outer limit where tidal-locking becomes
impossible (though the further from the star, the more precisely the
initial rotation has to happen to match the synchronous rate, so the
chances of this happening drop pretty precipitously past a couple AU
from a sun-mass star, for example). At the other extreme, a planet
can only start out spinning so fast before it would tear itself apart
with the centrifugal forces (in Earth's case the limit is about
2-hour days), so that gives us a more definitive inner limit where
tidal-locking may be unavoidable (in this simple model, anyway).
 
[tide2]
"h" indicates initial rotation rate in hours.

Finally, the planet's size and the nature of its response to tidal
forces also have a small influence on the tidal-locking rate. The
latter is a bit hard to pin down in a model so often represented as a
single "dissipation factor"; it's generally taken to be about 12 for
modern earth, but based on some models of the Earth's orbital
evolution, may have been as high as 100 in the past.
 
[tide3]
"M" indicates mass relative to Earth and "Q" indicates dissipation
factor; assuming an Earthlike composition, the 0.1 M planet has 49%
Earth's radius and the 10 M planet has 179%.

Altogether, combinations of these factors give us a pretty wide grey
zone where tidal-locking may occur depending on the particulars of
the planet in question (and this is all based on a fairly simplistic
model of tidal-locking; more detailed modelling can complicate
matters further^24).
 
[tide4]
 
This still leaves a significant range of stars below around 2/3 the
sun's mass where tidal-locking seems inevitable across at least part
of the habitable zone, but there are more complex factors that may
play into that, which brings us to...

Maybe Planets Won't Tidal-Lock

This isn't a widespread claim but it has started appearing lately in
response to a couple recent papers investigating how additional tidal
influences might prevent tidal-locking of planets that--based on the
sort of simple modelling we went over above--we would expect to lock
otherwise.

First is a 2015 paper^24 modelling the influence of a planet's
thermal tide, a bulging of its atmosphere due to thermal expansion by
day, and finding that in some cases it could act against the
influence of the gravitational tides to prevent full tidal-locking,
instead settling a planet into rotation slightly faster or slower
than 1:1 resonance. The implications have seemingly been a bit
garbled in interpretation; I've heard it claimed that the paper
implies that any planet with an atmosphere will avoid tidal-locking
around stars more than 1/4 the sun's mass, but the paper itself
claims that an atmosphere 10 times denser than Earth's could prevent
tidal locking for planets in the outer edge of the habitable zone of
stars about 28% the sun's mass, but a more Earthlike atmosphere
likely wouldn't stop tidal-locking near the inner HZ edge even for
stars almost 70% the sun's mass.

[Screenshot]
Limits at which thermal tides prevent tidal-locking for different
atmospheric pressures (10 bar, 1 bar, and a Venus-like atmosphere of
~100 bar); you can see there's a nonlinear relationship between
atmosphere and tidal-locking tendency. Dots are known exoplanets.
Leconte et al. 2015^25

Finer complexities like the planet's climate (affecting the thermal
tides) and ocean geometry (affecting the gravitational tides) likely
have an influence as well, and could perhaps allow for a planet to
resist tidal-locking for a period of its history only to fall into it
later on.

A more recent^26 set^27 of^28 papers^29 has examined the tidal
influence of multiple planets on each other in tightly-packed systems
such as TRAPPIST-1. In these cases it seems that, though a planet may
tidal-lock initially, the competing influences may cause chaotic
shifts between synchronous and non-synchronous rotation, and
substantial drift of the planet's orientation even when close to
synchronous. Because such tightly-packed systems are expected to be
common for small stars, this might indicate that such irregular
rotation is the norm, rather than perfect tidal-locking. But the
TRAPPIST-1 system is an extreme case, being near the minimum size for
a main sequence star and so having its planets in very close orbits,
with quite a few planets packed closely together even for a star of
its type--the closest approach between the two innermost planets is
less than twice the distance from the Earth to the Moon. For a more
moderate case, say, a planet pair orbiting a star half the sun's
mass, these chaotic interactions can still occur^26 but it seems to
take a substantially larger neighboring planet orbiting quite close
in something near to an orbital resonance. Planets in more loosely
packed systems (or completely alone) could still experience tidal
locking around any of these stars.

Still, because this mechanism is strongest for the smallest stars, it
neatly fills the gaps left by the other mechanisms that could prevent
tidal-locking; there is, it seems no range of stellar masses for
which perfect 1:1 synchronous rotation is the only guaranteed outcome
for habitable-zone planets, nor is there a specific range beyond
which tidal-locking is forbidden, though the overall trends
definitely still favor more frequent tidal-locking for smaller stars.

Besides these new proposals, it's been known for some time that
planets with some initial orbital eccentricity could end up^30 locked
into various other types of spin-orbit resonances, giving them a more
regular day and night cycle--though a quite slow one. Such resonances
aren't necessarily as stable, though; in the habitable zones of the
smallest stars, they could be accompanied by intense tidal heating^31
, enough to partially melt their interiors and alter their tidal
dynamics enough to break the resonance and settle into the more
typical 1:1 resonance.

As mentioned, a large, close-orbiting moon could also outcompete a
star's influence and force the planet to tidal-lock to it rather than
the star, giving the planet more regular days and nights. However, in
any such case the overall interactions between star, planet, and moon
will cause the moon's orbit to migrate towards or away from the
planet (more likely the latter for the mutually tidal-locked state),
and the moon can only migrate so far before escaping the planet's
orbit or falling below its Roche limit and breaking apart. The closer
the planet to the star and the stronger the tidal forces involved,
the quicker this will happen, so Earthlike habitable-zone planets
orbiting stars less than about half the sun's mass are unlikely^32 to
be able to retain a moon for as long as Earth's current age.

[moon]
Rough limits for where planets in Earthlike habitable
orbits can retain moons of varying composition for at least          
5 billion years. Sasaki and Barnes 2014^32

 

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1 Colose, C. M., Haqq-Misra, J., Wolf, E. T., Del Genio, A. D.,
Barnes, R., Way, M. J., & Ruedy, R. (2021). Effects of Spin-Orbit
Resonances and Tidal Heating on the Inner Edge of the Habitable Zone.
The Astrophysical Journal, 921(1), 25.
2 Joshi, M. M., Haberle, R. M., & Reynolds, R. T. (1997). Simulations
of the atmospheres of synchronously rotating terrestrial planets
orbiting M dwarfs: conditions for atmospheric collapse and the
implications for habitability. Icarus, 129(2), 450-465.
3 Haqq-Misra, J., Wolf, E. T., Joshi, M., Zhang, X., & Kopparapu, R.
K. (2018). Demarcating circulation regimes of synchronously rotating
terrestrial planets within the habitable zone. The Astrophysical
Journal, 852(2), 67.
4 Boutle, I. A., Mayne, N. J., Drummond, B., Manners, J., Goyal, J.,
Lambert, F. H., ... & Earnshaw, P. D. (2017). Exploring the climate
of Proxima b with the Met Office Unified Model. Astronomy &
Astrophysics, 601, A120.
5 Yang, J., Cowan, N. B., & Abbot, D. S. (2013). Stabilizing cloud
feedback dramatically expands the habitable zone of tidally locked
planets. The Astrophysical Journal Letters, 771(2), L45.
6 Dole, S. H. (1970). Habitable planets for man. American Elsevier
Publishing Company.
7 Cohen, M. (1981). Stellar influences on the emergence of
intelligent life. In In: Life in the universe; Proceedings of the
Conference, Moffett Field, CA, June 19, 20, 1979.(A82-22976 09-55)
Cambridge, MA, MIT Press, 1981, p. 115-118. (Vol. 2156, pp. 115-118).
8 Stevenson, D. S., & Stevenson, D. S. (2019). Atmospheric
Circulation and Climate. Red Dwarfs: Their Geological, Chemical, and
Biological Potential for Life, 171-218.
9 Kasting, J. F. (1996). Planetary atmosphere evolution: Do other
habitable planets exist and can we detect them?. Astrophysics and
space science, 241, 3-24.
10 Merlis, T. M., & Schneider, T. (2010). Atmospheric dynamics of
Earth-like tidally locked Aquaplanets. Journal of Advances in
Modeling Earth Systems, 2(4).
11 Yang, J., Liu, Y., Hu, Y., & Abbot, D. S. (2014). Water trapping
on tidally locked terrestrial planets requires special conditions.
The Astrophysical Journal Letters, 796(2), L22.
12 Hu, Y., & Yang, J. (2014). Role of ocean heat transport in
climates of tidally locked exoplanets around M dwarf stars.
Proceedings of the National Academy of Sciences, 111(2), 629-634.
13 Checlair, J. H., Olson, S. L., Jansen, M. F., & Abbot, D. S.
(2019). No snowball on habitable tidally locked planets with a
dynamic ocean. The Astrophysical Journal Letters, 884(2), L46.
14 Sergeev, D. E., Lambert, F. H., Mayne, N. J., Boutle, I. A.,
Manners, J., & Kohary, K. (2020). Atmospheric convection plays a key
role in the climate of tidally locked terrestrial exoplanets:
Insights from high-resolution simulations. The Astrophysical Journal,
894(2), 84.
15 Hu, Y. (2015). Exo-oceanography, climate, and habitability of
tidal-locking exoplanets in the habitable zone of M dwarfs. IAU
General Assembly, 29, 2245847.
16 Tarter, J. C., Backus, P. R., Mancinelli, R. L., Aurnou, J. M.,
Backman, D. E., Basri, G. S., ... & Young, R. E. (2007). A
reappraisal of the habitability of planets around M dwarf stars.
Astrobiology, 7(1), 30-65.
17 Leconte, J., Forget, F., Charnay, B., Wordsworth, R., Selsis, F.,
Millour, E., & Spiga, A. (2013). 3D climate modeling of close-in land
planets: circulation patterns, climate moist bistability, and
habitability. Astronomy & Astrophysics, 554, A69.
18 Sasaki, T., Barnes, J. W., & O'Brien, D. P. (2012). Outcomes and
duration of tidal evolution in a star-planet-moon system. The
Astrophysical Journal, 754(1), 51.
19 Millholland, S. (2023, September). Spin Dynamics of Planets in
Resonant Chains: An Abundance of High Obliquities. In AAS/Division of
Dynamical Astronomy Meeting (Vol. 55, No. 5, pp. 401-05).
20 Wang, Y., Liu, Y., Tian, F., Hu, Y., & Huang, Y. (2017). Effects
of eccentricity on climates and habitability of terrestrial
exoplanets around M dwarfs. arXiv preprint arXiv:1710.01405.
21 Kasting, J. F., Whitmire, D. P., & Reynolds, R. T. (1993).
Habitable zones around main sequence stars. Icarus, 101(1), 108-128.
22 Zsom, A., Seager, S., De Wit, J., & Stamenkovic, V. (2013). Toward
the minimum inner edge distance of the habitable zone. The
Astrophysical Journal, 778(2), 109.
23 Ramirez, R. M., & Kaltenegger, L. (2017). A volcanic hydrogen
habitable zone. The Astrophysical Journal Letters, 837(1), L4.
24 Barnes, R. (2017). Tidal locking of habitable exoplanets.
Celestial Mechanics and Dynamical Astronomy, 129, 509-536.
25 Leconte, J., Wu, H., Menou, K., & Murray, N. (2015). Asynchronous
rotation of Earth-mass planets in the habitable zone of lower-mass
stars. Science, 347(6222), 632-635.
26 Vinson, A. M., & Hansen, B. M. (2017). On the spin states of
habitable zone exoplanets around M dwarfs: the effect of a
near-resonant companion. Monthly Notices of the Royal Astronomical
Society, 472(3), 3217-3229.
27 Vinson, A. M., Tamayo, D., & Hansen, B. M. (2019). The chaotic
nature of TRAPPIST-1 planetary spin states. Monthly Notices of the
Royal Astronomical Society, 488(4), 5739-5747.
28 Shakespeare, C. J., & Steffen, J. H. (2023). Day and night:
habitability of tidally locked planets with sporadic rotation.
Monthly Notices of the Royal Astronomical Society, 524(4), 5708-5724.
29 Chen, H., Li, G., Paradise, A., & Kopparapu, R. K. (2023).
Sporadic Spin-orbit Variations in Compact Multiplanet Systems and
Their Influence on Exoplanet Climate. The Astrophysical Journal
Letters, 946(2), L32.
30 Dobrovolskis, A. R. (2007). Spin states and climates of eccentric
exoplanets. Icarus, 192(1), 1-23.
31 Makarov, V. V., Berghea, C. T., & Efroimsky, M. (2018).
Spin-orbital tidal dynamics and tidal heating in the TRAPPIST-1
multiplanet system. The Astrophysical Journal, 857(2), 142.
32 Sasaki, T., & Barnes, J. W. (2014). Longevity of moons around
habitable planets. International Journal of Astrobiology, 13(4),
324-336.
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Comments

 1. [blank]
    AnonymousMarch 7, 2024 at 1:42 PM

    Another concern with tidally-locked planets orbiting small-mass
    stars (particularly red dwarfs) is that they tend to be flare
    stars which can strip the atmosphere and sterilise life.

    Also, given a tidally-locked planet with an Earth-like atmosphere
    and an average temperature of 15degc at the terminator line, I
    wonder how hot the substellar point could get...

    ReplyDelete
    Replies
     1. [blogger_lo]
        Worldbuilding PastaMarch 7, 2024 at 3:13 PM

        I considered adding a section on the flare stars thing but
        wanted to keep this post from getting too long and it's a
        somewhat more ambiguous case; I did go over it a bit in a
        previous post https://worldbuildingpasta.blogspot.com/2019/06
        /an-apple-pie-from-scratch-part-ii-stars.html#latem but the
        short version is that there's still a fair bit of uncertainty
        regarding exactly how harsh flaring might be to a typical
        orbiting planet and it probably varies between different
        types of stars ("red dwarf" really covers a pretty diverse
        range) and even different individual stars. In particular
        there seems to be a tendency to calm down with age, and the
        properties of the planet itself also matter; often survival
        of an atmosphere isn't really a matter of avoiding loss so
        much as being able to replace lost gasses from internal
        reservoirs.

        Delete
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