mfb said:No. They could slowly increase their altitude and burn fuel forever - quite inefficient, but it would be possible.
=> No, they do not have to reach escape velocity anywhere.gaIiIeo said:Do spacecraft [...] have to reach escape velocity in any point of travel to leave Earth
So when you state "leave earth", you mean to "leave earth" so that the object never returns or end up orbiting the earth? (Otherwise, you can just jump up and you've left the Earth for a brief moment). Also I assume you're ignoring the effect of other objects in space such as orbiting or landing on the moon as method to "leave earth".gaIiIeo said:Do spacecraft (so we're talking about powered object) have to reach escape velocity in any point of travel to leave earth.
If you can control your thrust with arbitrary precision, a finite amount of fuel is sufficient. Get a bit below escape velocity, cruise for a long time (increasing your distance) to a point where the escape velocity is 1/4 of the previous value, repeat (using 1/4, 1/16, 1/64, ... of the fuel burnt in the first step, with a finite sum).rcgldr said:Assuming a finite exhaust velocity and a finite ratio of (mass of fuel) / (mass of spacecraft ), eventually you'll run out of fuel. At this point the rocket will need to have achieved the escape velocity required for that distance from the earth, but at very large distances, the escape velocity will be very small.
I didn't consider this possibility since I didn't do the math to see if a finite amount of fuel could keep a rocket below escape velocity but away from the Earth for an infinite time. I'm not sure if a radial path (straight out) versus a curved path makes a difference. The math for this may be what the OP is asking for.mfb said:If you can control your thrust with arbitrary precision, a finite amount of fuel is sufficient. Get a bit below escape velocity, cruise for a long time (increasing your distance) to a point where the escape velocity is 1/4 of the previous value, repeat (using 1/4, 1/16, 1/64, ... of the fuel burnt in the first step, with a finite sum).
rcgldr said:I didn't consider this possibility since I didn't do the math to see if a finite amount of fuel could keep a rocket below escape velocity but away from the Earth for an infinite time. I'm not sure if a radial path (straight out) versus a curved path makes a difference. The math for this may be what the OP is asking for.
Escape velocity is the minimum speed an object needs to achieve in order to break free from the gravitational pull of a planet or other celestial body. It is typically measured in kilometers per second (km/s) and varies depending on the mass and radius of the planet.
The formula for calculating escape velocity is v = √(2GM/r), where G is the gravitational constant, M is the mass of the planet, and r is the distance from the center of the planet to the object. This formula takes into account the gravitational force and the object's potential energy.
Escape velocity is important because it determines the minimum speed needed for a spacecraft or satellite to leave the Earth's orbit and travel to other celestial bodies. It also plays a crucial role in understanding the dynamics of the solar system and the universe.
Yes, escape velocity can be exceeded. In fact, many spacecraft and satellites travel at speeds much greater than escape velocity in order to reach their destination. However, exceeding escape velocity does not necessarily mean an object will escape a planet's gravity, as other factors such as atmospheric drag must also be taken into account.
Besides the mass and radius of a planet, other factors that can affect escape velocity include the planet's atmosphere, the altitude from which the object is launched, and the direction and angle of launch. These factors can alter the amount of energy needed to reach escape velocity and successfully leave a planet's gravitational pull.