Gravitational Energy and Kepler's Law

In summary: I didn't check it with a calculator.Anyway, I hope that helps.In summary, the conversation discusses a double-star system with two stars of equal mass rotating around the system's center of mass at a radius of 2.0 * 10^11 m. The common angular speed can be found using the formula a=v^2/r, where v is the velocity and r is the radius. If a meteoroid passes through the center of mass perpendicular to the orbital plane, it must have a minimum speed of 2.24 x 10^4 m/s in order to escape to infinity from the two-star system.
  • #1
jetsfan101202
10
0
1. In a double-star system, two stars of mass 6.0 *10^30 kg each rotate about the system's center of mass at a radius of 2.0 * 10^11 m.

(a) What is their common angular speed?

(b) If a meteoroid passes through the system's center of mass perpendicular to their orbital plane, what minimum speed must it have at the center of mass if it is to escape to "infinity" from the two-star system?

Homework Equations



F=-GMm/r^2
A=V^2/R
V(orbit)=sqrt(GM/r)
U(gravitational potential energy) = -GMm/R

The Attempt at a Solution



I tried to do F=ma and a=v^2/r so m(v^2/r)=GMm/r^2

any help would be greatly appreciated. I need this done by midnight. thanks so much
 
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  • #2
Welcome to PF!

In all circular orbit problems, begin with the fact that the centripetal force is the gravitational force: Fc = Fg
Put in the two detailed formulas for the forces (with the mass and radius in them). Then you can solve for the velocity or period easily. And one more step to get the angular velocity.
 
  • #3
isn't that what I did in my attempt at a solution? the only other thing I realize is that the force of gravity is 2r not r. so m(v^2/r)=GMm/(2r^2). Do I need two separate equations for both stars?
 
  • #4
Sorry, jetsfan - I failed to see that you already had done what I suggested!
Now I don't understand why you are stalled.
You have v² = GM/(4r) so v = 2.24 x 10^4 m/s.
From there you can get ω = v/r in a moment . . . and you're done.
Oh, is it the wrong answer?
 

1. What is gravitational energy and how does it relate to Kepler's Law?

Gravitational energy is the potential energy stored in an object due to its position in a gravitational field. Kepler's Law, also known as the Law of Planetary Motion, states that the orbit of a planet around the sun is an ellipse with the sun at one of the two foci. This law is related to gravitational energy as the gravitational force between the planet and the sun is what keeps the planet in its orbit, and this force is directly proportional to the distance between the two objects.

2. What is the formula for gravitational energy?

The formula for gravitational energy is E = -GmM/r, where E is the gravitational energy, G is the gravitational constant, m and M are the masses of the two objects, and r is the distance between them. This formula shows that as the distance between the two objects increases, the gravitational energy decreases.

3. How does Kepler's Law explain the motion of planets?

Kepler's Law explains the motion of planets by stating that the orbit of a planet around the sun is an ellipse, with the sun at one of the two foci. This means that the planet's distance from the sun varies throughout its orbit, causing it to move faster when it is closer to the sun and slower when it is farther away. This is due to the gravitational force between the two objects, which is stronger when they are closer together.

4. Can Kepler's Law be applied to other objects besides planets?

Yes, Kepler's Law can be applied to any two objects that have a gravitational force between them. This includes objects such as moons orbiting around planets, or even artificial satellites orbiting around Earth. As long as there is a gravitational force between two objects, Kepler's Law can be used to describe their motion.

5. How does the mass of an object affect its gravitational energy?

The mass of an object directly affects its gravitational energy. As the mass of an object increases, its gravitational energy also increases. This is because a larger mass creates a stronger gravitational force, which requires more energy to overcome. Therefore, the more massive an object is, the more gravitational energy it possesses.

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