Earth as Moon of Gas Giant: Effects on Sunlight?

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In summary, the size of the disc on the sky will vary depending on the inclination of the orbit. For an orbit inclined as much as, or more, than 33 degrees, there will be times when the eclipses are shorter than the t we calculated, varying in a sinusoidal fashion from 0 to t.
  • #1
willstaruss22
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Lets say Earth as a moon of a gas giant. Let's say it orbited the gas giant the size of Saturn every 24 hours. I understand that the part facing away from the gas giant would have a day/night cycle like the planet Earth but what about the side facing the gas giant? Would it get any sunlight before the gas giant eclipsed the sun? I am interested in what that would look like also?
 
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  • #2
Let's assume the planet, or moon in this case, is tidally locked so that its rotational period is equal to its orbital period. It would have a regular day/night cycle except for when the Sun is eclipsed by the gas giant. A 24 hours orbit is very very close and there would probably be a great many solar eclipses. In fact, there may be one every day. But as the gas giant would only block light for a portion of the orbit, there wouldn't be any point on the moon's surface that was in perpetual nighttime. Also, as the gas giant orbits around the Sun the time of the eclipse would gradually change over the course of the year with different parts of the moon being eclipsed at different times of the year.
 
  • #3
Do you have an estimate of the amount of time the eclipse would occur. Like maybe a 1 hour eclipse?
 
  • #4
It's relatively straightforward.
But perhaps you'd like to calculate this yourself?

First, let's find out the radius of the orbit.
You want to take the force of gravity between two bodies of masses equal to those of Earth's and Saturn's respectively, and compare that force to the one needed to keep the "moon" in a nice circular orbit(for simplicity's sake, and a good approximation anyway) - that is: centripetal force.

You end up with Fg=Fc

Where
Fg=GmM/r2
Fc=mrω2
and
the angular velocity ω=2∏/T
where T is one day(or 86400s)

So:
GM/r2=r4∏2/T2

GMT2=r34∏2

finally
r=(GMT2/4∏2)1/3

I'll let you plug in all the numbers.(remember to use T in seconds)


With that ready, let's see what size will the Saturn's disc appear on the sky:

2R/r=θ

where 2R is Saturn's diameter, r is the distance we've just calculated, and θ is the angular size(in radians) it'll have.

Now we know how big it is on the sky. How fast does it move across it then?
It goes a full circle in 1day, so its apparent angular velocity on the sky is:

ε=2∏/T

with that velocity, it obscures any point in the sky for:

t=θ/ε

seconds.
Now, at the distance of 10AU(Saturn's orbit) from the Sun, the Sun's disc is 1/100th of the half a degree in angular size we see on Earth. So let's just treat it as a point-like source of light that spends the above calculated t time obscured by Saturn's disc. And that's your eclipse duration.

Of course, that'd only work for the "moon"'s orbit perfectly aligned with that of Saturn's around the Sun. Should it be inclined, the eclipses' periods will change.
If the "moon"'s orbit inclination is higher than θ, then there will be times in the ~30 year long, well, year, when there are no eclipses, and times when the eclipses are shorter than the t we calculated, varying in a sinusoidal fashion from 0 to t.
In such case the eclipses would last full t time precisely twice in a year.

If the inclination is less than θ, the eclipse times will similarly vary between t and some value x, where t>x>0.


Yeah, so I did go ahead and plugged some numbers in, just to check if the results are roughly sensible, and I got:
r=200000km {~1/2th the distance from Earth to Moon and some 50000 km above the Satrun's Roche limit}
θ=0.6 rad {which is roughly 33 degrees, or 1/6th of the sky}
ε=7*10-5 rad/s
t=~8500s {2.3 hours}

An orbit inclined as much as, or more, than 33 degrees for a large moon seems unlikely, so the actual eclipse times would most likely never go below two hours for modestly inclined orbits.
 
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  • #5
Let's try again. Also I find that choice of different units can make the computations easier to follow and check for errors.

24 h orbit around Earth is about 42 200 km from Earth centre
Saturn is about 95 Earth masses

As noted in the previous derivation, the radius of a given period orbit is proportional to the cube root of the primary mass;
cube root of 95 is about 4,55
so we are looking at orbital radius of about 190 000 km (as stated, about half Earth-Moon distance).
The length of orbit is about 1 200 000 km
and speed on orbit about 50 000 km/h.

At equinoxes, the daily eclipse would be almost 2 and a half hours. This would still leave over 9 and a half hours of sunlight.

Add the shine of the planet at night, and some twilight in planet´s atmosphere at beginnings and ends of eclipses.

But I believe there was a gross error in estimating the orbital angle needed to evade eclipse.
YES, the size, as in diametre, of Saturn would be about 33 degrees.

But you will NOT need to get as far as diametre to evade the eclipse!

It is sufficient to get as far as radius.

Earth inclination 23,5 degrees has sine of about 0,4
so at solstices, the centre of Earth would pass about 76 000 km from the shadow centreline, and the winter polar circle about 6000 km closer. Still 70 000 km
Since the polar radius of Saturn is only 55 000 km, over the 190 000 km the shadow would diverge by around 1800 km (relying on Earth at 1 au), to then 55 900 km (excessive precision here meant for illustration) of penumbra and 54 100 km of umbra. Both much less than the 70 000 km from polar circle to eclipse centreline.
 
  • #6
snorkack said:
But you will NOT need to get as far as diametre to evade the eclipse!

It is sufficient to get as far as radius.
Duh!
Of course! Thanks for pointing that out.
 
  • #7
willstaruss22 said:
Lets say Earth as a moon of a gas giant. Let's say it orbited the gas giant the size of Saturn every 24 hours. I understand that the part facing away from the gas giant would have a day/night cycle like the planet Earth but what about the side facing the gas giant? Would it get any sunlight before the gas giant eclipsed the sun? I am interested in what that would look like also?

Interesting question. A 24-hour orbit is very close, maybe too close to be realistic. I think Io is about one-and-one half days. Every point on the "moon" would get sunlight, though some points maybe half of what other points get

By fiddling with the inclination of the "lunar" orbit you can get whatever frequency of eclipse you like, I would think. But normally there would be many eclipses, many more than here on Earth.

Would the difference in temperature during the orbit be noticeable, as the planet went closer and further from the Sun? I'd think it would be.

Jupiter has a huge EM field and that would make a big difference. Look up the "Io flux tube." There is a great deal of energy there.

There would be so much light reflected from the giant that the phase would make a big difference. When "full" then night would be like a day with overcast, I would expect.
 
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  • #8
ImaLooser said:
Interesting question. A 24-hour orbit is very close, maybe too close to be realistic. I think Io is about one-and-one half days.
Of smaller bodies, Thebe is 16 hours; Mimas is just under 23 hours.
ImaLooser said:
Every point on the "moon" would get sunlight, though some points maybe half of what other points get
Obviously depending on inclination! In case of low inclination, you have the demonstration that the subplanetary point gets about 80 % the sunlight of far side by time, and slightly less by amount (can someone compute how much?), whereas the poles obviously get 0% by amount.
ImaLooser said:
By fiddling with the inclination of the "lunar" orbit you can get whatever frequency of eclipse you like, I would think. But normally there would be many eclipses, many more than here on Earth.
You have a hard maximum on inclination at 90 degrees.
ImaLooser said:
Would the difference in temperature during the orbit be noticeable, as the planet went closer and further from the Sun? I'd think it would be.
Hardly. Earth goes 2,5 million km closer and further, and we cannot notice.
ImaLooser said:
Jupiter has a huge EM field and that would make a big difference. Look up the "Io flux tube." There is a great deal of energy there.
Yes, and Saturn has far weaker field in comparison.
ImaLooser said:
There would be so much light reflected from the giant that the phase would make a big difference. When "full" then night would be like a day with overcast, I would expect.

Perhaps, yes.

We are speaking of a disc roughly 5000 times bigger in area than Moon. How will the albedo compare, for a gas giant in habitable zone?

At subplanetary point, the planet would never be less than half at night. Crescent planet can only be seen at night on east and west edges of near side.

Precisely how is east, west, north and south defined outside Earth?
 

1. How does being a moon of a gas giant affect the sunlight Earth receives?

Being a moon of a gas giant can significantly affect the sunlight Earth receives. The gas giant acts as a shield, blocking and absorbing a portion of the sunlight that would otherwise reach Earth. This results in Earth receiving less sunlight than it would if it were not a moon of a gas giant.

2. What impact does this have on Earth's climate and temperature?

The reduced amount of sunlight reaching Earth as a moon of a gas giant can have a significant impact on the planet's climate and temperature. Less sunlight means less heat energy, resulting in cooler temperatures. This can lead to changes in weather patterns, as well as affect the growth and survival of plants and animals.

3. How does the gas giant's atmosphere affect the amount and type of sunlight reaching Earth?

The gas giant's atmosphere can also affect the amount and type of sunlight reaching Earth. The gas giant's atmosphere can scatter and absorb different wavelengths of light, resulting in a different type of light reaching Earth. This can have implications for plant growth and photosynthesis, as well as the amount of heat energy reaching Earth's surface.

4. Are there any positive effects of Earth being a moon of a gas giant?

While there may be some negative effects, there are also some potential positive effects of Earth being a moon of a gas giant. The gas giant's gravitational pull can help stabilize Earth's orbit, preventing it from straying too far or too close to the sun. Additionally, the gas giant's presence can also help protect Earth from potential asteroid impacts.

5. How does the distance between Earth and the gas giant affect the sunlight received?

The distance between Earth and the gas giant can play a significant role in the amount of sunlight Earth receives. If the gas giant is too close, it can block too much sunlight, resulting in cooler temperatures. However, if the gas giant is too far away, it may not have as much of an impact on the sunlight reaching Earth. The distance must be just right for the perfect balance of sunlight and temperature on Earth.

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