The path of our planetary bodies

In summary: The mass distribution of the solar system is not uniform at one instant of time and its such that the center of mass lies at one of the foci of an ellipse and the planets revolve around the sun maintaining that equilibrium set by the mass distribution, resulting in an elliptical orbit.In summary, the path of the planets in our solar system is elliptical because of the influence of other planets and the gravitational attraction due to other planets, which hinder the perfectly circular path. The planets also revolve around the center of mass of the solar system, which is located at one of the foci of an ellipse, in order to maintain equilibrium. This results in an elliptical orbit rather than a circular one.
  • #1
misskitty
737
0
Hello everyone,

Its good to FINALLY be back! :biggrin: I was wondering why the path of the planets in our solar system is elliptical and not circular?

~Kitty
 
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  • #2
The sun is the centre of all forces that provides the planets the necessary centripedal forces to help move around the sun, but the influence of other planets and gravitational attraction due to other planets hinders this perefectly circular path, making it elliptical.
 
  • #3
How much force do the other planets have on one another? Do the satelites that orbit the planets also have a small effect on the path of the planet?
 
  • #4
You do not need the other planets.

To have a circular orbit both the direction and the magnitude of the velocity of a planet has to be exactly right for the gravitational attraction of the Sun to keep them on a circular orbit.

In general this is not so and hence the plants' orbits are elliptical.

The question is: "Why are they nearly circular"?

I think the answer to that lies in the way the planets accreted from the solar nebula; those not on a nearly circular orbit would have collided or been ejected by now.

Garth.
 
  • #5
Another reason could be that the centre of mass of the solar system( sun + 9 planets) lies at one of the foci of an ellipse to maintain the equillibrium or in other words the whole mass of the solar system is distributed in such a manner that the C.M has to lie at one of the foci of an ellipse and not at the centre of a circle...

Not to mention the planets revolve around the CM (a focus of the ellipse) that lies inside the sun thereby forming an elliptical path
 
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  • #6
misskitty said:
Hello everyone,

Its good to FINALLY be back! :biggrin: I was wondering why the path of the planets in our solar system is elliptical and not circular?

~Kitty

I'm not sure what sort of answer you're looking for. The simplest one I can think of is that it's because gravity is an inverse square law central force.

The fact that gravity is a central force means that angular momentum is conserved. This provides one constraint equation. When you add in the fact that the force law is an inverse square one, the law of conservation of energy plus the law of the conservation of momentum from the fact that gravity is a central force completely determines the shape of the orbit.
 
  • #7
Pervect, the answer you gave make sense to me.

Panthera, the solar system resting on one foci of an ellipse rather than the center of a circle fits. If we are at one foci of the ellipse, then what is one the other?

Why don't our planets orbit the sun the way an electron would a nucleus? Is it because the paths would be so unpredictable there would be a high likelyhood of our planet colliding with one of the others?
 
  • #8
misskitty said:
Pervect, the answer you gave make sense to me.

Panthera, the solar system resting on one foci of an ellipse rather than the center of a circle fits. If we are at one foci of the ellipse, then what is one the other?

Why don't our planets orbit the sun the way an electron would a nucleus? Is it because the paths would be so unpredictable there would be a high likelyhood of our planet colliding with one of the others?

hey i posted 3 times..1st the connection went off, then server problem and now i am tired...well i am posting wait
 
  • #9
misskitty said:
Pervect, the answer you gave make sense to me.

Panthera, the solar system resting on one foci of an ellipse rather than the center of a circle fits. If we are at one foci of the ellipse, then what is one the other?

Why don't our planets orbit the sun the way an electron would a nucleus? Is it because the paths would be so unpredictable there would be a high likelyhood of our planet colliding with one of the others?

we are not at one of the foci but our(solar system's) CM is...the mass distribution of the solar system is not uniform at one instant of time and its such that the CM lies at one of the foci of an ellipse...for example consider that you put different masses of balls in a bag ..the bag will tilt towards the heavier part (as the gravitational attraction will be more there)and CM won't lie at the center but somewhere at the side (near the massive part) similarly the plane having the sun and the planets have nonuniform mass distribution and the CM atomatically adjusts itself (to maintain equqillibrium) in such a way that it results in an elliptical plane with sun having the CM( its well known fact that the CM lies inside the sun)...and the planets revolve around the sun maintaining that equillibrium set by the mass distribution or in other words in an elliptical orbit..


hope its clear
ps- i am really tired and my explanation got modified as this is the 4 th time...
 
  • #10
misskitty said:
Why don't our planets orbit the sun the way an electron would a nucleus? Is it because the paths would be so unpredictable there would be a high likelyhood of our planet colliding with one of the others?

If you are asking why the planets are more-or-less in a plane (the ecliptic), I'd say it's because the sun and planets condensed from a swirling cloud of gas.

This swirling cloud of gas has an axis around which it swirls. The plane perpendicular to this axis is the plane that most bodies orbit in. There are a few oddball planets like Pluto, which have to be explained.

See for instance

http://hyperphysics.phy-astr.gsu.edu/hbase/eclip.html
 
  • #11
panthera said:
hey i posted 3 times..1st the connection went off, then server problem and now i am tired...well i am posting wait

I know how this is. :grumpy: Believe me I have lost a few posts myself because of a sketchy internet connection. I hope your connection this time is more stable. :smile:

Your post answering my question makes sense. Just to make sure I have it, it's not so much we are on one of the foci of the ellipse but we form the ellipse with the sun as the foci and us traveling in the ellipitcal path around it.
If you are asking why the planets are more-or-less in a plane (the ecliptic), I'd say it's because the sun and planets condensed from a swirling cloud of gas.

Pervect said:
This swirling cloud of gas has an axis around which it swirls. The plane perpendicular to this axis is the plane that most bodies orbit in. There are a few oddball planets like Pluto, which have to be explained.

I don't know much about the formation of the planets. I did know about the swirling cloud of gas, but wasn't there some rock like matter that formed with the gas to create the planets? The plane perpendicular to the axis on which the planet are on now right? So did the planets move from where they were formed to wear they are now? :uhh:
 
  • #12
misskitty said:
Your post answering my question makes sense. Just to make sure I have it, it's not so much we are on one of the foci of the ellipse but we form the ellipse with the sun as the foci and us traveling in the ellipitcal path around it.

Right! That's one of Kepler's laws, there are also two other parts to the laws, one of which is "equal areas are swept out in equal times".

http://home.cvc.org/science/kepler.htm [Broken]

Before we get off on a tanget:

I'm not sure if I understood the rest of your question

Why don't our planets orbit the sun the way an electron would a nucleus?

I took a guess and interpreted this as you asking why the planets were all in the same plane. (It wasn't clear to me what you meant by "not like an electron would a nucleus", most pictures of atoms don't have the electrons all in a plane, so I guessed this was what you were asking about). Was that in fact your original question?
 
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  • #13
I wonder if many exo-solar systems have planets orbiting like the traditional picture of an atom, all in different planes. Most star systems are binary. And if they're wide binaries, with the stars orbiting in different planes than the planets, a few billion years should give the Kozai Mechanism enough time to completely scramble the planets' inclinations.

I would guess that a wide binary, even if it formed with the stars and planets in the same plane, could have the stars out of plane with the planets, just like Oort Cloud members aren't necessarily in the plane of our Sun's planets. Stellar passages would pull the wide member into a different inclination.
 
  • #14
I really haven't thought about the binary star situation very much - thanks for an interesting post, I'll have to think about your ideas more before I can give any sort of coherent answer.

I do hope we haven't scared Miss Kitty too much :-).

I did find an interesting illustration of the Oort cloud - it's apparently thought to be non-uniform due to tidal forces, so it's not spherically symmetric, though it's definitely not planar. I'm not sure if we have any actual data on the distrubution of bodies in the cloud, or whether this is all just theory at this point.

http://www.solarviews.com/eng/oort.htm
http://www.solarviews.com/raw/comet/oort.jpg
 
  • #15
pervect said:
Right! That's one of Kepler's laws, there are also two other parts to the laws, one of which is "equal areas are swept out in equal times".

Ah! YAY the brain does work during summer holiday! :biggrin:

Pervect said:
I'm not sure if I understood the rest of your question
I took a guess and interpreted this as you asking why the planets were all in the same plane. (It wasn't clear to me what you meant by "not like an electron would a nucleus", most pictures of atoms don't have the electrons all in a plane, so I guessed this was what you were asking about). Was that in fact your original question?

You got it. I wasn't sure how best to articulate my thought so I took a a stab at it and hoped someone might get it. :smile: So yes, why are all the planets on one plane with one orbit, but the electrons of an atom are flying around in many different paths? :bugeye:

~Kitty
 
  • #16
Whoa! There's a few phrases people are tossing out here and I have NO clue what they mean. :bugeye:

Could someone please explain what these are?:
Exo-solar system
Binaries/wide binaries
Kozai Mechanism

I briefly skimmed the article Pervect posted with the picture of the Oort cloud and the brief description of what it is. Is there an Oort cloud surrounding our galaxy? How many Oort clouds exist that we know of? How were they discovered, when, and by whom?

Nah, you guys aren't scaring me with this. Don't worry. :smile:

~Kitty
 
  • #17
misskitty said:
Whoa! There's a few phrases people are tossing out here and I have NO clue what they mean. :bugeye:

Could someone please explain what these are?:
Exo-solar system

Planets of other stars. A fair number of them have been discovered in the last few years by astronomers.

Binaries/wide binaries

Pairs of stars that orbit each other under gravity. Some are farther apart (wider) than others.

Kozai Mechanism

Don't know this. I'll google it and see what I can add in edit.
(added in edit) See http://www.spaceref.com/news/viewsr.html?pid=16463, it's a mechanism to explain the fact that most exo solar planets have highly eccentric orbits. That just means their orbits are long thin ellipses instead of round fat ones like the orbit of the Earth. The Kozai mechanism says that perturbations (repeated weak gravity pulls) from a binary companion star to their parent star could make this happen.

I briefly skimmed the article Pervect posted with the picture of the Oort cloud and the brief description of what it is. Is there an Oort cloud surrounding our galaxy? How many Oort clouds exist that we know of? How were they discovered, when, and by whom?

Duh, by Oort. He was a Dutch astronomer who figured out that the orbits of the comets all had an "other end" at similar distances from the Sun. So he figured there was a huge ring of cometary material circling far out beyond the orbit of Pluto (or Neptune!), and this came to be called the Oort Cloud. Oort clouds are harder to see than planets. I don't know if even ours has ever been physically detected in situ. BTW it's around our Solar System - the Sun and the planets, not our galaxy - the milky way with 100 billion stars.
 
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  • #18
selfAdjoint said:
...it's a mechanism to explain the fact that most exo solar planets have highly eccentric orbits...
And although that link doesn't mention it, it can also tinker with the the planet's inclinations BIG TIME (up to 90 degrees).
 
  • #19
What do you mean it can alter their orbits up to 90 degrees? Some planets will orbit their suns perpendicluar to the other orbits?
 
  • #20
misskitty said:
What do you mean it can alter their orbits up to 90 degrees? Some planets will orbit their suns perpendicluar to the other orbits?
Actually, that's what I was wondering. I don't believe we've found any exo solar systems with planets in multiple planes yet.

Jupiter has dozens of outer moons orbiting it. Many are in highly inclined orbits. But around 60 degrees it ends. There are no moons in polar orbits.

Under certain circumstances, the Kozai Mechanism causes a periodic exchange between high inclination and high eccentricity. The orbit of a moon in a 90 degree orbit would become so elliptical that it would crash into Jupiter. Slightly less than 90 degrees would cause it orbit at times to become elliptical enough that it would pass through the inner moon region (Io, Europa, Ganymede, Callisto) where it would be gravitationally ejected from the Jovian system, or crash into one of those moons.

So although the Kozai Mechanism is capable of forcing things into polar (90 degree) orbits, these orbits are fatal.

I don't see any reason that wide binary star systems should behave any differently.
 
  • #21
That is insane. Do we know what the most extreme angle of orbit is so far? Is there a general angle that most satilites follow? Do any moons orbit their planet in a counterclockwise motion? Why?
 
  • #22
What is the point of having the Kozai Mechanism if it doesn't do anything but cause satilies to crash into their orbiting body after achieving an orbit of 90 degrees?
 
  • #23
misskitty said:
What is the point of having the Kozai Mechanism if it doesn't do anything but cause satilies to crash into their orbiting body after achieving an orbit of 90 degrees?

Why does it have to have a point? It is simply a natural process. It doesn't care what the end result is.
 
  • #24
It doesn't have to have a point. I was just wondering if there was one.:smile:
 
  • #25
misskitty said:
Do any moons orbit their planet in a counterclockwise motion? Why?
I think you mean retrograde. Clockwise and counter clockwise depend on which direction you are looking from. By convention, we tend to look "down" at the solar system such that natural "direct" orbits travel in a counterclockwise direction. So in this case a retrograde orbit would be clockwise.
To answer your question, yes, some do. These are "captured" moons. captured moons are more likely to orbit retrograde, because it is easier for them to pull passing bodies into this type of orbit. As an aside, these orbits are not long term stable. Just as our moon is moving away from the Earth due to tidal action, moons in retrograde orbits tend to move in. Eventually they will be pulled into the point where, if they are big enough, they will be torn apart and form a ring, or if they are not, they will hit the planet.
 
  • #26
About force laws: inverse square produces ellipses, but it is not the only one. Harmonic spring law is where the force = the distance, so the farther you get the more force you feel, like pulling on a spring. This law produces ellipses where the sun is at the center, not at a focus. Another property about this law is that n-body problems always have repetive solutions, with the planets ALLWAYS going back to the exact same spot over and over again.

For inverse linear law or below, escape velocity for anybody is infinite.

For inverse cube law and above, a stable orbit is impossible. But stable orbits exist for anything below inverse cube. Even inverse 2.999999... law.
 

What is the path of our planetary bodies?

The path of our planetary bodies refers to the orbit or trajectory that each planet follows around the sun. This includes their distance from the sun, the shape of their orbit, and the time it takes for them to complete one revolution around the sun.

What is the shape of the path of our planetary bodies?

The shape of the path of our planetary bodies is an ellipse, with the sun at one of the two foci. This means that the distance between the planet and the sun varies throughout its orbit, with the closest point being the perihelion and the farthest point being the aphelion.

Why do planets follow a specific path around the sun?

Planets follow a specific path around the sun because of the gravitational force between the two objects. This force keeps the planets in orbit around the sun, and the specific path is determined by the balance between the planet's velocity and the gravitational pull of the sun.

Do all planets have the same path around the sun?

No, not all planets have the same path around the sun. Each planet has its own unique orbit, with variations in the shape and distance from the sun. For example, Mercury has a highly elliptical orbit, while Venus has a nearly circular orbit.

Can the path of our planetary bodies change over time?

Yes, the path of our planetary bodies can change over time due to various factors such as gravitational interactions with other celestial bodies, external forces, and changes in the mass or position of the planets. These changes can occur over long periods of time and may not be noticeable in our lifetime.

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