Total Mechanical Energy & Escape Velocity: Explained

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Total mechanical energy must be zero for an object to achieve escape velocity because, at infinite distance from Earth, gravitational potential energy becomes zero. Since gravity is a conservative force, the total mechanical energy remains constant, and a positive total energy allows for escape, while negative energy prevents it. The escape velocity represents the minimum speed needed for an object to leave Earth's gravitational influence without falling back. This concept highlights the relationship between kinetic and potential energy in the context of gravitational fields. Understanding these principles is essential for studying motion in astrophysics and space exploration.
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Hi,

I just had a question that why the total mechanical energy has to be zero in order for an object to achieve escape velocity?

Thanks!
 
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Basically when we want a body to escape the gravitational field of earth, what we want is that it goes far away from the vicinity of earth. Far away from the earth, the gravitational potential energy is zero and because gravity is a conservative force the total mechanical energy is same throughout i.e. zero. Also note that this is a limiting case, even if the the total mechanical energy is positive the body will escape but it cannot escape the field if the total energy is negative.
 
Perhaps, it may be better to say that if we throw a body directly up, we don't want the body ever to fall back on earth. That minimum speed for that is the escape speed. The rest is as harshant said.
 

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