Need Help Creating Moons for Fiction Story

In summary, Warren was trying to figure out the sidereal months of two moons orbiting a planet, but was not able to figure it out. He was able to find the period of the other planet by using Kepler's laws.
  • #1
Super**Nova
7
0
I'm not a big astronomy whiz or anything, nor am I great at math, but I need help.

For some reason or other, I can't seem to figure this out. I have 2 moons for a planet I'm writing about, and I need to accurately figure out their sidereal months.

The planet has 722 days a year. Moon #1's synodic period is rounded off to 48 days, and moon #2's synodic period is 80 days. To me, it's a simplistic, and probably lazy way to calculate periods between phases since those are multiples of 8. Never mind the distance from the planet each moon is (I really don't think it matters, but correct me if I'm wrong). I can't figure out their sidereal months for the life of me.

Assuming one synodic month begins at "new" phase, I'd like to know the days and hours after one synodic month for each moon, after doing a complete 360° around the planet, to reach "new" again for its sidereal month. If anyone can figure this out for me, that would be great. However I'd like to know how you reached your conclusions so I can figure out future problems like this on my own.

P.S. There's a rival planet that crosses my story's main planet ever 412 days (between the main planet and the sun), keeping in mind that, like the moons, both the rival planet and the main planet are revolving around the sun in the same direction. My question is, if the rival planet crosses the main planet every 412 days (that's 412 main planet days), how many days does the rival planet take to revolve around the sun?

Thank you.
 
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  • #2
Real moons are often tidally-locked to their planets, which makes their synodic periods some multiple of their sidereal periods. For example, the Moon is tidally-locked to the Earth, in a 1:1 ratio, so its synodic and sidereal periods are the same (it rotates once per orbit). 3:2, 4:1, 5:2, or any other ratio of whole numbers is also possible, but 1:1 is the most energetically favorable.

- Warren
 
  • #3
The distance to the moon certainly is relevant to its period. Moons, like any orbiting objects, obey Kepler's laws. Of relevance here is the fact that the ratio of the squares of the periods of two moons of the same planet must equal the ratio of the cubes of the average radii of their orbits.
 
  • #4
HallsofIvy said:
The distance to the moon certainly is relevant to its period. Moons, like any orbiting objects, obey Kepler's laws. Of relevance here is the fact that the ratio of the squares of the periods of two moons of the same planet must equal the ratio of the cubes of the average radii of their orbits.

Is speed of orbit also a factor?
 
  • #5
As far as the sidereal month goes you can use the formula:

[tex]P_{sidreal} = \frac{1}{\frac{1}{P_{planet}+ \frac{1}{P_{synodic}}}[/tex]

which gives

[tex]\frac{1}{\frac{1}{722}+ \frac{1}{48}}} = 45.2 days[/tex]

for the one moon and

[tex]\frac{1}{\frac{1}{722}+ \frac{1}{80}}} = 72.5 days[/tex]

for the other.

You can find the period of the other planet by the same method by substituting the time it takes between "passings" for the synodic month.

This should give you an answer of about 269 days.
 
  • #6
Janus said:
As far as the sidereal month goes you can use the formula:

[tex]P_{sidreal} = \frac{1}{\frac{1}{P_{planet}+ \frac{1}{P_{synodic}}}[/tex]

which gives

[tex]\frac{1}{\frac{1}{722}+ \frac{1}{48}}} = 45.2 days[/tex]

for the one moon and

[tex]\frac{1}{\frac{1}{722}+ \frac{1}{80}}} = 72.5 days[/tex]

for the other.

You can find the period of the other planet by the same method by substituting the time it takes between "passings" for the synodic month.

This should give you an answer of about 269 days.

Oh wow, thank you so much! That saved a lot of embarrassing guess work! I really appreciate it.
 

1. How many moons can a planet have?

The number of moons a planet can have varies greatly and depends on factors such as the size and gravitational pull of the planet. For example, Earth has one moon, while Jupiter has 79 known moons.

2. How are moons formed?

There are several theories on how moons are formed, but the most widely accepted one is the impact theory. This theory suggests that moons are formed when a large object, such as a planet or asteroid, collides with a smaller object, such as a planetesimal, and the debris from the impact forms into a moon.

3. Can moons have their own moons?

Yes, it is possible for moons to have their own moons, although they are typically much smaller and less stable compared to planets having moons. Some examples of moons with moons include Jupiter's moon, Callisto, and Saturn's moon, Titan.

4. How do moons affect their host planet?

Moons can have a significant impact on their host planet. They can affect the planet's rotation, tides, and even its atmosphere. For example, Earth's moon helps stabilize its axial tilt, which is essential for maintaining a stable climate on the planet.

5. Can moons support life?

It is possible for moons to support life, but it is highly dependent on factors such as the moon's size, distance from its host planet, and the presence of liquid water. Some moons, such as Jupiter's moon Europa and Saturn's moon Enceladus, are thought to have subsurface oceans that could potentially support life.

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