Q&A for How to Calculate Escape Velocity

Yes. What is different, and what was not made clear perhaps, is that escape velocity is the velocity required at the start of movement for un-powered flight, as for example if you were to throw a stone. If you have enough fuel, then you can escape as slowly as you like. When I walk upstairs I am escaping the earths gravity a tiny bit, but I can't go on for long.

Both of you are. Conservation of energy does not depend on the propulsion that got you to space. Remember that escape velocity refers to the velocity of an object at sea level. If an explosion sends an object flying away at that speed, it will escape Earth. In your case, constant propulsion generates a constant force which steadily increases velocity, and is another (the practical) way to achieve escape velocity.

In reality, yes, because our planet isn't a perfect sphere, which means the radius varies (lowest at poles & highest at equator). So the escape velocity varies from place to place. But for the sake of school physics problems and such, it's generally assumed that the escape velocity is the same all over the planet.

Let's start from Newton's universal gravitational law, F = GMm/r^2. Weight is a measure of force, F = mg, where g is the gravitational acceleration. So, g = GM/r^2. We can therefore rewrite escape velocity as v = sqrt(2gr). On Earth, it would be g = 9.81 m/s^2. You are given that the weight of an object on the moon is 1/6th of that on Earth, so divide g by 6 and use the moon's radius to solve for v.

The object will have some velocity left after travelling an infinite distance from Earth.

You would need the gravitational constant (G) to assist here... 6.67x10e-11. With the gravitational constant in play, and the mass of earth (m) known, you can back calculate the radius of the planet (g=Gm/r^2). With the radius of the planet known, you can then calculate escape velocity with v=(2GM/r)^.5.

Escape velocity is inversely proportional to the square root of the radius: v ~ 1/sqrt(r). So If we want 10v, we have to decrease r by 100 (write 10v ~ 1/sqrt(r) and divide both sides by 10, and put the 10 in the square root). r_e = 6371 km, so r = 63.71 km.

"Velocity" means displacement per unit time. Displacement can only be >=0. So the answer is, No, escape velocity can never be negative.

ve = √(2GM/r) ve[moon] = √{2G(M/18)/(r/4)} = √{(2GM/r)*(4/18)} = 11.2•(√2/3) = 5.27973 km/s

Jupiter is a gaseous planet, therefore the equation would be 6.67x10e-6; the reason this occurs is because the gas giants are generally easier to get in and out of.

It will come back to earth. The bullet cannot escape the earth's gravitational pull.

Indeed, Newton's Gravity Equation reads: Fg = GMm/r^2. (Note that Fg is a force.) To derive the potential energy from this force, we need to integrate, and this is where the square disappears: U = integral from {r = infinite} to {r=r} of Fg dr. This equals -GMm/r @ {r=r} minus -GMm/r @ {r=infinite}, which boils down to U = -GMm/r.

It stands for "speed," which is distance over time.

Some parts of a planet are denser than others, but this variety in density is usually so small that it does not affect the result, so no, the density does not need to be constant.

Use the equation v = sqrt(2 x G x M/r), where G is the gravitational constant, M is the mass of Earth and r is the radius of Earth.

v=(2GM/r)^1/2 v=((2*6.674*10^-11*5.98*10^24)/6.4*10^6)^1/2 v=11.139m/s