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Question
Derive an expression for the energy of satellite.
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Solution
The total energy of the satellite is the sum of its kinetic energy and gravitational potential energy. The potential energy of the satellite is,
U = `-("GM"_"s""M"_"E")/(("R"_"E" + "h"))` ......(1)
Here Ms – mass of the satellite, ME – mass of the Earth, RE – radius of the Earth.
The Kinetic energy of the satellite is
K.E = `1/2"M"_"s""v"^2` .............(2)
Here v is the orbital speed of the satellite and is equal to
v = `sqrt("GM"_"E"/(("R"_"E" + "h")))`
Substituting the value of v in (2) the kinetic energy of the satellite becomes,
K.E = `1/2("GM"_"E""M"_"s")/(("R"_"E" + "h"))`
Therefore the total energy of the satellite is
E = `1/2("GM"_"E""M"_"s")/(("R"_"E" + "h")) - ("GM"_"s""M"_"E")/(("R"_"E" + "h"))`
E = `-("GM"_"s""M"_"E")/(2("R"_"E" + "h"))`
The negative sign in the total energy implies that the satellite is bound to the Earth and it cannot escape from the Earth.
As h approaches ∞, the total energy tends to zero. Its physical meaning is that the satellite is completely free from the influence of Earth’s gravity and is not bound to Earth at a large distance.
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