Because the formulas for Coulomb's law and Newton's law of gravity have the same inverse-square law dependence on distance, a formula analogous to the formula for Gauss's law can be found for gravity. The gravitational field g at a location is the force per unit mass on a test mass mo placed at that location. (Then, for a point mass m at the origin, the gravitational field g at some position 7' is g = -(GNm/r²) f.) (a) Compute the flux of the gravitational field through a spherical surface of radius r, and verify that the gravitational analog of Gauss's law is Þ₂ = fg. dà = -47Gymencl- (b) What do you think is the differential form of Gauss's law for gravitation? (c) Determine the gravitational field, g, a distance r from the center of the Earth (where r ≤RE, where Re is the radius of the Earth), assuming that the Earth's density is uniform. Express your answer in terms of GN, the mass of the Earth, ME, and RE.

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Because the formulas for Coulomb's law and Newton's law of gravity have the same inverse-square law dependence on distance, a formula analogous to the formula for Gauss's law can be found for gravity. The gravitational ficld g at a location is the force per unit mass on a test mass mo placed at that location. (Then, for a point mass m at the origin, the gravitational ficld g at some position 7 is g = - (GNm/r2)î.) (a) Compute the flux of the gravitational field through a spherical surface of radius r, and verify that the gravitational analog of Gauss's law is dÃ= -4nGNMencl- 6. (b) What do you think is the differential form of Gauss's law for gravitation? (c) Determine the gravitational ficld, g, a distance r from the center of the Earth (where r < Rp, where Rp is the radius of the Earth), assuming that the Earth's density is uniform. Express your answer in terms of GN, the mass of the Earth, МЕ, and Rp.