ビデオ: Potential Energy due to Gravitation

An object of mass m initially at a distance r₁ from the Earth's center, is displaced to r₂. Since the object moves in Earth's gravitational field, its potential energy changes from U₁ to U₂. The change in the potential energy is equal to the work done by the gravitational force to displace the object.

Here, the work done equals the negative integral of magnitudes of gravitational force and displacement. On substituting for gravitational force and integrating within the limits of r₁ and r₂, U₂minusU₁ equals gravitational constant times the product of the two masses multiplied by one over r₁ minus one over r₂.

Considering the distance r₂ as infinity, where the Earth's gravitational field is negligible, the potential energy U₂ equals zero.

Therefore, the gravitational potential energy for any two masses separated by a distance r is expressed as minus G times the product of two masses, divided by r.

Typically, the potential energy increases as the masses move farther apart. Its maximum value is zero for masses at an infinite distance from each other.

Since gravitational force is a conservative force, the amount of work done to move an object between two points in the gravitational field in which it resides is independent of the path taken. Thus, similar to the gravitational field, a gravitational potential energy function can be defined, which depends only on spatial coordinates.

Consider a mass gravitationally bound to another object. For example, the Earth is gravitationally bound to the Sun’s gravitational field. The potential energy of the Earth in the Sun’s gravitational field is defined such that its value is negative close to the Sun and increases to zero at large distances from the Sun.

Since the Earth and the Sun are not special cases, the result can be generalized for any two objects. Thus, under the influence of gravity, all masses fall from a higher to lower potential energy while their kinetic energies increase. Hence, the definition is consistent with the conservation of energy principle. If the total energy of a system is positive, it is not gravitationally bound.

The magnitude of the potential energy decreases with the distance between the two objects. It is inversely proportional to the distance because of the inverse-square dependence of the gravitational force on the distance.

This text is adapted from Openstax, University Physics Volume 1, Section 13.3: Gravitational Potential Energy and Total Energy.

タグ

Gravitational Force Conservative Force Work Done Potential Energy Gravitational Field Spatial Coordinates Mass Binding Earth Sun Kinetic Energy Conservation Of Energy Gravitational Binding Inverse square Law Distance Total Energy

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