Star
Object Statistical Data
Mass (kg) 2.39E+30
Radius (m) 737,500,000
Diameter (km) 1,475,000
Surface Gravity (m/sec?) 292.7
Volume (m?) 1.6794E+27
Density (g/cm?) 1.42
Surface Area (km?) 6,831,462,500,000
Planet
Object Statistical Data
Mass (kg) 8.71E+24
Radius (m) 7,184,500
Diameter (km) 14,369
Surface Gravity (m/sec?) 11.3
Volume (m?) 1.55259E+21
Density (g/cm?) 5.61
Surface Area (km?) 648,310,026
Object Orbital Data
Orbital Distance (AU) 1.169
Orbital Distance (m) 174,879,910,838
Velocity (m/sec) 30,172
Orbital Period (sec) 36,399,766
Orbital Period (days) 421
I was wondering if any one could take a quick look at this planet
The star is Sol like, but has 1.2 times mass; this should just place it in the F5-G0 category, and the planet is 1.169 time further then the earth. Anyway what I was wondering is pure (intelligent) speculation on what the planet would be like around the star.
Thanks
What would it be like? Speculation on what the planet would.
I think its a hypothetical scenerio he derived...
I think alot depends on the chemistry of the planet itsself...Theres not much to go on except our own solar system...I suppose you could come up with just about anything to a point...but there is also these links that might help you out some:
http://www.dausha.net/sciences/orbits.shtml
http://cfa-www.harvard.edu/iau/lists/MPNames.html
http://www.brandubh.com/worldbuilding.htm
I think alot depends on the chemistry of the planet itsself...Theres not much to go on except our own solar system...I suppose you could come up with just about anything to a point...but there is also these links that might help you out some:
http://www.dausha.net/sciences/orbits.shtml
http://cfa-www.harvard.edu/iau/lists/MPNames.html
http://www.brandubh.com/worldbuilding.htm
I'm trying to teach the cavemen how to play scrabble, its uphill work. The only word they know is Uhh and they dont know how to spell it!
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Stargazer_2098
- Posts: 64
- Joined: 02.05.2002
- With us: 22 years 6 months
- Location: Starship Thor Heyerdahl, continuing voyage
Life might be possible in the upper-atmosphere of a gas-giant, some even belive there is life on Jupiter and Saturn.
However, this life would not be like anything we have here on earth, and would most likely be very primitive creatures.
If theres life on Jupiter, it will also have evolved an protection against heavy radiation, and thunderbolts as powerful as 30 nuclear bombs.
These life-forms will have to live in the very upper reaches of the atmosphere, since the pressure further down would be... crushing.
Stargazer.
However, this life would not be like anything we have here on earth, and would most likely be very primitive creatures.
If theres life on Jupiter, it will also have evolved an protection against heavy radiation, and thunderbolts as powerful as 30 nuclear bombs.
These life-forms will have to live in the very upper reaches of the atmosphere, since the pressure further down would be... crushing.
Stargazer.
"We have lingered long enough on the shores of the cosmic ocean.
We are ready to set sail towards the stars" --- Carl Sagan, Cosmos.
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Member of the Noctis IV and Orbiter communities;
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We are ready to set sail towards the stars" --- Carl Sagan, Cosmos.
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Member of the Noctis IV and Orbiter communities;
Visit Noctis
Visit Orbiter
Give all things being equal 1.2 times the mass means 1.44 times the atmospheric pressure. So about 21.6 PSI for the atmosphere.
As for the temperature on the planet this is what I’m having trouble with, mainly because I’m lazy.
But given that the sun averages 5,800 degrees Kelvin. A star that is 1.2 solar masses should have about 6,400 degrees Kelvin this places it between a class F5 and G0
150,000,000km & 5,800 degrees Kelvin
5800/150m^2 = 2.57x10-13 * 510,000,000km surface area = 1.31x10-4 total energy absorbed per square km
earths average temp is 60°F (15°C)
175,000,000km & 6,400 degrees Kelvin
6400/175m^2 = 2.1x10-13 * 650,000,000km surface area = 1.36x10-4 total energy absorbed per square km
So this planet has an average temp of about 60°F (15°C) if the atmosphere was identical to earths
now all I need to do is factor pressure which should be about 1.44 time greater that should mean that the temperature is now about 86°F (21°C)
so depending on the humidity this would either be a hot humid world or a desert world. (guess I need to rethink the star so the planet is more like earth.)
Can someone check over my BS math to see if I got it correct? Its a drastic simplification but should work.
As for the temperature on the planet this is what I’m having trouble with, mainly because I’m lazy.
But given that the sun averages 5,800 degrees Kelvin. A star that is 1.2 solar masses should have about 6,400 degrees Kelvin this places it between a class F5 and G0
150,000,000km & 5,800 degrees Kelvin
5800/150m^2 = 2.57x10-13 * 510,000,000km surface area = 1.31x10-4 total energy absorbed per square km
earths average temp is 60°F (15°C)
175,000,000km & 6,400 degrees Kelvin
6400/175m^2 = 2.1x10-13 * 650,000,000km surface area = 1.36x10-4 total energy absorbed per square km
So this planet has an average temp of about 60°F (15°C) if the atmosphere was identical to earths
now all I need to do is factor pressure which should be about 1.44 time greater that should mean that the temperature is now about 86°F (21°C)
so depending on the humidity this would either be a hot humid world or a desert world. (guess I need to rethink the star so the planet is more like earth.)
Can someone check over my BS math to see if I got it correct? Its a drastic simplification but should work.