Is a Titan-like planet with Earth-like gravity plausible?
For my hard sci-fi story, I would like to have a planet similar to Titan (very cold, nitrogen atmosphere, methane seas) but with a surface gravity in the region of 1g. Could this occur, or would the greater gravity result in a significantly different atmosphere?
planets hard-science
asked Dec 3 '18 at 3:11
Megalonychidae
614513
This question asks for hard science. All answers to this question should be backed up by equations, empirical evidence, scientific papers, other citations, etc. Answers that do not satisfy this requirement might be removed. See the tag description for more information.
add a comment |
For my hard sci-fi story, I would like to have a planet similar to Titan (very cold, nitrogen atmosphere, methane seas) but with a surface gravity in the region of 1g. Could this occur, or would the greater gravity result in a significantly different atmosphere?
planets hard-science
asked Dec 3 '18 at 3:11
Megalonychidae
614513
This question asks for hard science. All answers to this question should be backed up by equations, empirical evidence, scientific papers, other citations, etc. Answers that do not satisfy this requirement might be removed. See the tag description for more information.
add a comment |
For my hard sci-fi story, I would like to have a planet similar to Titan (very cold, nitrogen atmosphere, methane seas) but with a surface gravity in the region of 1g. Could this occur, or would the greater gravity result in a significantly different atmosphere?
planets hard-science
asked Dec 3 '18 at 3:11
Megalonychidae
614513
For my hard sci-fi story, I would like to have a planet similar to Titan (very cold, nitrogen atmosphere, methane seas) but with a surface gravity in the region of 1g. Could this occur, or would the greater gravity result in a significantly different atmosphere?
planets hard-science
planets hard-science
asked Dec 3 '18 at 3:11
Megalonychidae
614513
asked Dec 3 '18 at 3:11
Megalonychidae
614513
asked Dec 3 '18 at 3:11
Megalonychidae
614513
asked Dec 3 '18 at 3:11
Megalonychidae
614513
asked Dec 3 '18 at 3:11
Megalonychidae
614513
614513
This question asks for hard science. All answers to this question should be backed up by equations, empirical evidence, scientific papers, other citations, etc. Answers that do not satisfy this requirement might be removed. See the tag description for more information.
This question asks for hard science. All answers to this question should be backed up by equations, empirical evidence, scientific papers, other citations, etc. Answers that do not satisfy this requirement might be removed. See the tag description for more information.
add a comment |
add a comment |
2 Answers
2
active
oldest
votes
Based on this chart
with Earth escape velocity and Titan temperature your planet should be able to keep nitrogen and methane, like you ask, but also water, ammonia, oxygen, helium, carbon dioxide and xenon. Hydrogen might be borderline.
If you don't have photosynthetic life forms it is likely that all the oxygen will be chemically bound to other atoms, due to its reactivity, and you will have no free oxygen.
answered Dec 3 '18 at 4:25
L.Dutch♦
76.9k25184374
as far as life in a non-polar sea, some people have worked out a membrane prototype, but no mention of a metabolic framework: popsci.com/heres-what-methane-based-life-titan-could-look
– theRiley
Dec 3 '18 at 9:00
This is a fantastic answer. Would the atmosphere be primarily nitrogen, water or ammonia? (or some combination thereof)
– Megalonychidae
Dec 3 '18 at 13:04
@Megalonychidae, I suspect that strongly depends on the composition of the cloud condensing to form the stellar system
– L.Dutch♦
Dec 3 '18 at 13:05
1
Venus reaches the temperature of 650K, not 350K. But that is not so important. The chart is simply senseless. Any atmosphere will run away at any temperature and any gravitation (save black holes). The difference is in TIME only. The chart must have a comment about what time interval of escaping half of the atmosphere is meant.
– Gangnus
Dec 3 '18 at 22:56
@Gangnus, there is no way to escape a gravity well with a velocity below its escape velocity. I don't know where you get your statement from.
– L.Dutch♦
Dec 4 '18 at 0:27
|
show 3 more comments
That depends on if the planet is sole or a satellite of a giant planet.
The presence of different chemical stuffs in the atmosphere or on the surface are defined:
For simple stuffs: by second cosmic velocity from one side and temperature and molecule weight from the other.
For complex stuffs: by second cosmic velocity from one side and temperature, atomic weight of the lightest component of the molecule and the radiation level in the exosphere from the other.
For both variants the speed of input of the stuff into the atmosphere is utterly important, too.
The processes are:
for simple stuffs: The speeds of molecules is distributed statistically. (https://www.khanacademy.org/science/physics/thermodynamics/temp-kinetic-theory-ideal-gas-law/a/what-is-the-maxwell-boltzmann-distribution) There are always some fraction that have velocities above the second cosmic. And that fraction, in higher heights will be dissipated into space. That defines the speed of output of the stuff. The speed of input and output are balanced.
For complex stuffs: The radiation makes molecules fell apart. And if they can, they are joining back. That can be prevented by the loss of a component.
For example, water is divided into hydrogen and oxygen. The first is lighter and has much higher speeds of molecules. And speed of losing water is defined by the fraction of hydrogen in water vapor (defined by radiation) and fraction of hydrogen molecules, free atoms or ions, having second cosmic speed (defined by temperature). The speed of oxygen is 256 times smaller (gases have same temperature/energy and H2 is 16 times lighter than O2, so lesser mass should be compensated by 16^2 times higher speed), so its losses are negligible in comparison and it is always enough oxygen to restore the water molecule back.
Again, the speed of coming and losing the stuff are balanced.
So:
1. It is not acceleration that is important for gas keeping in the atmosphere, but the second cosmic speed. For example Saturn has same acceleration as the Earth, but much higher second cosmic (35m/s2), and does not lose even hydrogen. The question is undefined in this part. Let us say, you need a planet that is more Earth-like and the second cosmic is the same as ours (11m/s2).
Titan on its place does not lose nitrogen. Neither would the Earth there. The water is frozen and lies as rock. The same would be on the Earth. Titan has some methane as liquid. Not much, for it escapes by radiation dissipation and hydrogen losing. The Earth would lose less hydrogen, so, much more methane will be left. Seas will be larger.
At its place, the Earth significantly loses only hydrogen and helium. The question is, what will be with them if the Earth will have the Titan temperature. For much H in atmosphere will cause reaction with N and ammonia will snow onto the surface, leaving no N in gas state.
(https://geosci.uchicago.edu/~kite/doc/Catling2009.pdf) - look for explanation below the chart on the 4th page.
According to the chart, if the planet will have the radiation and temperature as on Titan and second cosmic speed as on the Earth, the planet will NOT lose its hydrogen and as a result, it will have ammonia/hydrogen/helium atmosphere instead of the nitrogen one. Ammonia fells as snow and only H/He atmosphere remains. It will be so, if the planet will be separate one.
But if it will be the satellite of a giant, the giant and Earth magnetospheres will react, thus greatly heating up the exosphere layers (look at the Earth and giant planets temperatures on the chart). And it WILL lose its hydrogen and helium and mainly nitrogen remains.
answered Dec 5 '18 at 10:30
Gangnus
1,52539
add a comment |
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2 Answers
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active
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2 Answers
2
active
oldest
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active
oldest
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active
oldest
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Based on this chart
with Earth escape velocity and Titan temperature your planet should be able to keep nitrogen and methane, like you ask, but also water, ammonia, oxygen, helium, carbon dioxide and xenon. Hydrogen might be borderline.
If you don't have photosynthetic life forms it is likely that all the oxygen will be chemically bound to other atoms, due to its reactivity, and you will have no free oxygen.
answered Dec 3 '18 at 4:25
L.Dutch♦
76.9k25184374
as far as life in a non-polar sea, some people have worked out a membrane prototype, but no mention of a metabolic framework: popsci.com/heres-what-methane-based-life-titan-could-look
– theRiley
Dec 3 '18 at 9:00
This is a fantastic answer. Would the atmosphere be primarily nitrogen, water or ammonia? (or some combination thereof)
– Megalonychidae
Dec 3 '18 at 13:04
@Megalonychidae, I suspect that strongly depends on the composition of the cloud condensing to form the stellar system
– L.Dutch♦
Dec 3 '18 at 13:05
1
Venus reaches the temperature of 650K, not 350K. But that is not so important. The chart is simply senseless. Any atmosphere will run away at any temperature and any gravitation (save black holes). The difference is in TIME only. The chart must have a comment about what time interval of escaping half of the atmosphere is meant.
– Gangnus
Dec 3 '18 at 22:56
@Gangnus, there is no way to escape a gravity well with a velocity below its escape velocity. I don't know where you get your statement from.
– L.Dutch♦
Dec 4 '18 at 0:27
|
show 3 more comments
Based on this chart
with Earth escape velocity and Titan temperature your planet should be able to keep nitrogen and methane, like you ask, but also water, ammonia, oxygen, helium, carbon dioxide and xenon. Hydrogen might be borderline.
If you don't have photosynthetic life forms it is likely that all the oxygen will be chemically bound to other atoms, due to its reactivity, and you will have no free oxygen.
answered Dec 3 '18 at 4:25
L.Dutch♦
76.9k25184374
as far as life in a non-polar sea, some people have worked out a membrane prototype, but no mention of a metabolic framework: popsci.com/heres-what-methane-based-life-titan-could-look
– theRiley
Dec 3 '18 at 9:00
This is a fantastic answer. Would the atmosphere be primarily nitrogen, water or ammonia? (or some combination thereof)
– Megalonychidae
Dec 3 '18 at 13:04
@Megalonychidae, I suspect that strongly depends on the composition of the cloud condensing to form the stellar system
– L.Dutch♦
Dec 3 '18 at 13:05
1
Venus reaches the temperature of 650K, not 350K. But that is not so important. The chart is simply senseless. Any atmosphere will run away at any temperature and any gravitation (save black holes). The difference is in TIME only. The chart must have a comment about what time interval of escaping half of the atmosphere is meant.
– Gangnus
Dec 3 '18 at 22:56
@Gangnus, there is no way to escape a gravity well with a velocity below its escape velocity. I don't know where you get your statement from.
– L.Dutch♦
Dec 4 '18 at 0:27
|
show 3 more comments
Based on this chart
with Earth escape velocity and Titan temperature your planet should be able to keep nitrogen and methane, like you ask, but also water, ammonia, oxygen, helium, carbon dioxide and xenon. Hydrogen might be borderline.
If you don't have photosynthetic life forms it is likely that all the oxygen will be chemically bound to other atoms, due to its reactivity, and you will have no free oxygen.
answered Dec 3 '18 at 4:25
L.Dutch♦
76.9k25184374
Based on this chart
with Earth escape velocity and Titan temperature your planet should be able to keep nitrogen and methane, like you ask, but also water, ammonia, oxygen, helium, carbon dioxide and xenon. Hydrogen might be borderline.
If you don't have photosynthetic life forms it is likely that all the oxygen will be chemically bound to other atoms, due to its reactivity, and you will have no free oxygen.
answered Dec 3 '18 at 4:25
L.Dutch♦
76.9k25184374
answered Dec 3 '18 at 4:25
L.Dutch♦
76.9k25184374
answered Dec 3 '18 at 4:25
L.Dutch♦
76.9k25184374
answered Dec 3 '18 at 4:25
L.Dutch♦
76.9k25184374
76.9k25184374
as far as life in a non-polar sea, some people have worked out a membrane prototype, but no mention of a metabolic framework: popsci.com/heres-what-methane-based-life-titan-could-look
– theRiley
Dec 3 '18 at 9:00
This is a fantastic answer. Would the atmosphere be primarily nitrogen, water or ammonia? (or some combination thereof)
– Megalonychidae
Dec 3 '18 at 13:04
@Megalonychidae, I suspect that strongly depends on the composition of the cloud condensing to form the stellar system
– L.Dutch♦
Dec 3 '18 at 13:05
1
Venus reaches the temperature of 650K, not 350K. But that is not so important. The chart is simply senseless. Any atmosphere will run away at any temperature and any gravitation (save black holes). The difference is in TIME only. The chart must have a comment about what time interval of escaping half of the atmosphere is meant.
– Gangnus
Dec 3 '18 at 22:56
@Gangnus, there is no way to escape a gravity well with a velocity below its escape velocity. I don't know where you get your statement from.
– L.Dutch♦
Dec 4 '18 at 0:27
|
show 3 more comments
as far as life in a non-polar sea, some people have worked out a membrane prototype, but no mention of a metabolic framework: popsci.com/heres-what-methane-based-life-titan-could-look
– theRiley
Dec 3 '18 at 9:00
This is a fantastic answer. Would the atmosphere be primarily nitrogen, water or ammonia? (or some combination thereof)
– Megalonychidae
Dec 3 '18 at 13:04
@Megalonychidae, I suspect that strongly depends on the composition of the cloud condensing to form the stellar system
– L.Dutch♦
Dec 3 '18 at 13:05
1
Venus reaches the temperature of 650K, not 350K. But that is not so important. The chart is simply senseless. Any atmosphere will run away at any temperature and any gravitation (save black holes). The difference is in TIME only. The chart must have a comment about what time interval of escaping half of the atmosphere is meant.
– Gangnus
Dec 3 '18 at 22:56
@Gangnus, there is no way to escape a gravity well with a velocity below its escape velocity. I don't know where you get your statement from.
– L.Dutch♦
Dec 4 '18 at 0:27
as far as life in a non-polar sea, some people have worked out a membrane prototype, but no mention of a metabolic framework: popsci.com/heres-what-methane-based-life-titan-could-look
– theRiley
Dec 3 '18 at 9:00
as far as life in a non-polar sea, some people have worked out a membrane prototype, but no mention of a metabolic framework: popsci.com/heres-what-methane-based-life-titan-could-look
– theRiley
Dec 3 '18 at 9:00
This is a fantastic answer. Would the atmosphere be primarily nitrogen, water or ammonia? (or some combination thereof)
– Megalonychidae
Dec 3 '18 at 13:04
This is a fantastic answer. Would the atmosphere be primarily nitrogen, water or ammonia? (or some combination thereof)
– Megalonychidae
Dec 3 '18 at 13:04
@Megalonychidae, I suspect that strongly depends on the composition of the cloud condensing to form the stellar system
– L.Dutch♦
Dec 3 '18 at 13:05
@Megalonychidae, I suspect that strongly depends on the composition of the cloud condensing to form the stellar system
– L.Dutch♦
Dec 3 '18 at 13:05
1
1
Venus reaches the temperature of 650K, not 350K. But that is not so important. The chart is simply senseless. Any atmosphere will run away at any temperature and any gravitation (save black holes). The difference is in TIME only. The chart must have a comment about what time interval of escaping half of the atmosphere is meant.
– Gangnus
Dec 3 '18 at 22:56
Venus reaches the temperature of 650K, not 350K. But that is not so important. The chart is simply senseless. Any atmosphere will run away at any temperature and any gravitation (save black holes). The difference is in TIME only. The chart must have a comment about what time interval of escaping half of the atmosphere is meant.
– Gangnus
Dec 3 '18 at 22:56
@Gangnus, there is no way to escape a gravity well with a velocity below its escape velocity. I don't know where you get your statement from.
– L.Dutch♦
Dec 4 '18 at 0:27
@Gangnus, there is no way to escape a gravity well with a velocity below its escape velocity. I don't know where you get your statement from.
– L.Dutch♦
Dec 4 '18 at 0:27
|
show 3 more comments
That depends on if the planet is sole or a satellite of a giant planet.
The presence of different chemical stuffs in the atmosphere or on the surface are defined:
For simple stuffs: by second cosmic velocity from one side and temperature and molecule weight from the other.
For complex stuffs: by second cosmic velocity from one side and temperature, atomic weight of the lightest component of the molecule and the radiation level in the exosphere from the other.
For both variants the speed of input of the stuff into the atmosphere is utterly important, too.
The processes are:
for simple stuffs: The speeds of molecules is distributed statistically. (https://www.khanacademy.org/science/physics/thermodynamics/temp-kinetic-theory-ideal-gas-law/a/what-is-the-maxwell-boltzmann-distribution) There are always some fraction that have velocities above the second cosmic. And that fraction, in higher heights will be dissipated into space. That defines the speed of output of the stuff. The speed of input and output are balanced.
For complex stuffs: The radiation makes molecules fell apart. And if they can, they are joining back. That can be prevented by the loss of a component.
For example, water is divided into hydrogen and oxygen. The first is lighter and has much higher speeds of molecules. And speed of losing water is defined by the fraction of hydrogen in water vapor (defined by radiation) and fraction of hydrogen molecules, free atoms or ions, having second cosmic speed (defined by temperature). The speed of oxygen is 256 times smaller (gases have same temperature/energy and H2 is 16 times lighter than O2, so lesser mass should be compensated by 16^2 times higher speed), so its losses are negligible in comparison and it is always enough oxygen to restore the water molecule back.
Again, the speed of coming and losing the stuff are balanced.
So:
1. It is not acceleration that is important for gas keeping in the atmosphere, but the second cosmic speed. For example Saturn has same acceleration as the Earth, but much higher second cosmic (35m/s2), and does not lose even hydrogen. The question is undefined in this part. Let us say, you need a planet that is more Earth-like and the second cosmic is the same as ours (11m/s2).
Titan on its place does not lose nitrogen. Neither would the Earth there. The water is frozen and lies as rock. The same would be on the Earth. Titan has some methane as liquid. Not much, for it escapes by radiation dissipation and hydrogen losing. The Earth would lose less hydrogen, so, much more methane will be left. Seas will be larger.
At its place, the Earth significantly loses only hydrogen and helium. The question is, what will be with them if the Earth will have the Titan temperature. For much H in atmosphere will cause reaction with N and ammonia will snow onto the surface, leaving no N in gas state.
(https://geosci.uchicago.edu/~kite/doc/Catling2009.pdf) - look for explanation below the chart on the 4th page.
According to the chart, if the planet will have the radiation and temperature as on Titan and second cosmic speed as on the Earth, the planet will NOT lose its hydrogen and as a result, it will have ammonia/hydrogen/helium atmosphere instead of the nitrogen one. Ammonia fells as snow and only H/He atmosphere remains. It will be so, if the planet will be separate one.
But if it will be the satellite of a giant, the giant and Earth magnetospheres will react, thus greatly heating up the exosphere layers (look at the Earth and giant planets temperatures on the chart). And it WILL lose its hydrogen and helium and mainly nitrogen remains.
answered Dec 5 '18 at 10:30
Gangnus
1,52539
add a comment |
That depends on if the planet is sole or a satellite of a giant planet.
The presence of different chemical stuffs in the atmosphere or on the surface are defined:
For simple stuffs: by second cosmic velocity from one side and temperature and molecule weight from the other.
For complex stuffs: by second cosmic velocity from one side and temperature, atomic weight of the lightest component of the molecule and the radiation level in the exosphere from the other.
For both variants the speed of input of the stuff into the atmosphere is utterly important, too.
The processes are:
for simple stuffs: The speeds of molecules is distributed statistically. (https://www.khanacademy.org/science/physics/thermodynamics/temp-kinetic-theory-ideal-gas-law/a/what-is-the-maxwell-boltzmann-distribution) There are always some fraction that have velocities above the second cosmic. And that fraction, in higher heights will be dissipated into space. That defines the speed of output of the stuff. The speed of input and output are balanced.
For complex stuffs: The radiation makes molecules fell apart. And if they can, they are joining back. That can be prevented by the loss of a component.
For example, water is divided into hydrogen and oxygen. The first is lighter and has much higher speeds of molecules. And speed of losing water is defined by the fraction of hydrogen in water vapor (defined by radiation) and fraction of hydrogen molecules, free atoms or ions, having second cosmic speed (defined by temperature). The speed of oxygen is 256 times smaller (gases have same temperature/energy and H2 is 16 times lighter than O2, so lesser mass should be compensated by 16^2 times higher speed), so its losses are negligible in comparison and it is always enough oxygen to restore the water molecule back.
Again, the speed of coming and losing the stuff are balanced.
So:
1. It is not acceleration that is important for gas keeping in the atmosphere, but the second cosmic speed. For example Saturn has same acceleration as the Earth, but much higher second cosmic (35m/s2), and does not lose even hydrogen. The question is undefined in this part. Let us say, you need a planet that is more Earth-like and the second cosmic is the same as ours (11m/s2).
Titan on its place does not lose nitrogen. Neither would the Earth there. The water is frozen and lies as rock. The same would be on the Earth. Titan has some methane as liquid. Not much, for it escapes by radiation dissipation and hydrogen losing. The Earth would lose less hydrogen, so, much more methane will be left. Seas will be larger.
At its place, the Earth significantly loses only hydrogen and helium. The question is, what will be with them if the Earth will have the Titan temperature. For much H in atmosphere will cause reaction with N and ammonia will snow onto the surface, leaving no N in gas state.
(https://geosci.uchicago.edu/~kite/doc/Catling2009.pdf) - look for explanation below the chart on the 4th page.
According to the chart, if the planet will have the radiation and temperature as on Titan and second cosmic speed as on the Earth, the planet will NOT lose its hydrogen and as a result, it will have ammonia/hydrogen/helium atmosphere instead of the nitrogen one. Ammonia fells as snow and only H/He atmosphere remains. It will be so, if the planet will be separate one.
But if it will be the satellite of a giant, the giant and Earth magnetospheres will react, thus greatly heating up the exosphere layers (look at the Earth and giant planets temperatures on the chart). And it WILL lose its hydrogen and helium and mainly nitrogen remains.
answered Dec 5 '18 at 10:30
Gangnus
1,52539
add a comment |
That depends on if the planet is sole or a satellite of a giant planet.
The presence of different chemical stuffs in the atmosphere or on the surface are defined:
For simple stuffs: by second cosmic velocity from one side and temperature and molecule weight from the other.
For complex stuffs: by second cosmic velocity from one side and temperature, atomic weight of the lightest component of the molecule and the radiation level in the exosphere from the other.
For both variants the speed of input of the stuff into the atmosphere is utterly important, too.
The processes are:
for simple stuffs: The speeds of molecules is distributed statistically. (https://www.khanacademy.org/science/physics/thermodynamics/temp-kinetic-theory-ideal-gas-law/a/what-is-the-maxwell-boltzmann-distribution) There are always some fraction that have velocities above the second cosmic. And that fraction, in higher heights will be dissipated into space. That defines the speed of output of the stuff. The speed of input and output are balanced.
For complex stuffs: The radiation makes molecules fell apart. And if they can, they are joining back. That can be prevented by the loss of a component.
For example, water is divided into hydrogen and oxygen. The first is lighter and has much higher speeds of molecules. And speed of losing water is defined by the fraction of hydrogen in water vapor (defined by radiation) and fraction of hydrogen molecules, free atoms or ions, having second cosmic speed (defined by temperature). The speed of oxygen is 256 times smaller (gases have same temperature/energy and H2 is 16 times lighter than O2, so lesser mass should be compensated by 16^2 times higher speed), so its losses are negligible in comparison and it is always enough oxygen to restore the water molecule back.
Again, the speed of coming and losing the stuff are balanced.
So:
1. It is not acceleration that is important for gas keeping in the atmosphere, but the second cosmic speed. For example Saturn has same acceleration as the Earth, but much higher second cosmic (35m/s2), and does not lose even hydrogen. The question is undefined in this part. Let us say, you need a planet that is more Earth-like and the second cosmic is the same as ours (11m/s2).
Titan on its place does not lose nitrogen. Neither would the Earth there. The water is frozen and lies as rock. The same would be on the Earth. Titan has some methane as liquid. Not much, for it escapes by radiation dissipation and hydrogen losing. The Earth would lose less hydrogen, so, much more methane will be left. Seas will be larger.
At its place, the Earth significantly loses only hydrogen and helium. The question is, what will be with them if the Earth will have the Titan temperature. For much H in atmosphere will cause reaction with N and ammonia will snow onto the surface, leaving no N in gas state.
(https://geosci.uchicago.edu/~kite/doc/Catling2009.pdf) - look for explanation below the chart on the 4th page.
According to the chart, if the planet will have the radiation and temperature as on Titan and second cosmic speed as on the Earth, the planet will NOT lose its hydrogen and as a result, it will have ammonia/hydrogen/helium atmosphere instead of the nitrogen one. Ammonia fells as snow and only H/He atmosphere remains. It will be so, if the planet will be separate one.
But if it will be the satellite of a giant, the giant and Earth magnetospheres will react, thus greatly heating up the exosphere layers (look at the Earth and giant planets temperatures on the chart). And it WILL lose its hydrogen and helium and mainly nitrogen remains.
answered Dec 5 '18 at 10:30
Gangnus
1,52539
That depends on if the planet is sole or a satellite of a giant planet.
The presence of different chemical stuffs in the atmosphere or on the surface are defined:
For simple stuffs: by second cosmic velocity from one side and temperature and molecule weight from the other.
For complex stuffs: by second cosmic velocity from one side and temperature, atomic weight of the lightest component of the molecule and the radiation level in the exosphere from the other.
For both variants the speed of input of the stuff into the atmosphere is utterly important, too.
The processes are:
for simple stuffs: The speeds of molecules is distributed statistically. (https://www.khanacademy.org/science/physics/thermodynamics/temp-kinetic-theory-ideal-gas-law/a/what-is-the-maxwell-boltzmann-distribution) There are always some fraction that have velocities above the second cosmic. And that fraction, in higher heights will be dissipated into space. That defines the speed of output of the stuff. The speed of input and output are balanced.
For complex stuffs: The radiation makes molecules fell apart. And if they can, they are joining back. That can be prevented by the loss of a component.
For example, water is divided into hydrogen and oxygen. The first is lighter and has much higher speeds of molecules. And speed of losing water is defined by the fraction of hydrogen in water vapor (defined by radiation) and fraction of hydrogen molecules, free atoms or ions, having second cosmic speed (defined by temperature). The speed of oxygen is 256 times smaller (gases have same temperature/energy and H2 is 16 times lighter than O2, so lesser mass should be compensated by 16^2 times higher speed), so its losses are negligible in comparison and it is always enough oxygen to restore the water molecule back.
Again, the speed of coming and losing the stuff are balanced.
So:
1. It is not acceleration that is important for gas keeping in the atmosphere, but the second cosmic speed. For example Saturn has same acceleration as the Earth, but much higher second cosmic (35m/s2), and does not lose even hydrogen. The question is undefined in this part. Let us say, you need a planet that is more Earth-like and the second cosmic is the same as ours (11m/s2).
Titan on its place does not lose nitrogen. Neither would the Earth there. The water is frozen and lies as rock. The same would be on the Earth. Titan has some methane as liquid. Not much, for it escapes by radiation dissipation and hydrogen losing. The Earth would lose less hydrogen, so, much more methane will be left. Seas will be larger.
At its place, the Earth significantly loses only hydrogen and helium. The question is, what will be with them if the Earth will have the Titan temperature. For much H in atmosphere will cause reaction with N and ammonia will snow onto the surface, leaving no N in gas state.
(https://geosci.uchicago.edu/~kite/doc/Catling2009.pdf) - look for explanation below the chart on the 4th page.
According to the chart, if the planet will have the radiation and temperature as on Titan and second cosmic speed as on the Earth, the planet will NOT lose its hydrogen and as a result, it will have ammonia/hydrogen/helium atmosphere instead of the nitrogen one. Ammonia fells as snow and only H/He atmosphere remains. It will be so, if the planet will be separate one.
But if it will be the satellite of a giant, the giant and Earth magnetospheres will react, thus greatly heating up the exosphere layers (look at the Earth and giant planets temperatures on the chart). And it WILL lose its hydrogen and helium and mainly nitrogen remains.
answered Dec 5 '18 at 10:30
Gangnus
1,52539
answered Dec 5 '18 at 10:30
Gangnus
1,52539
answered Dec 5 '18 at 10:30
Gangnus
1,52539
answered Dec 5 '18 at 10:30
Gangnus
1,52539
1,52539
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