An astronaut working on the Moon tries to determine the gravitational constant G by throwing a Moon rock of mass m with a velocity of v vertically into the sky. The astronaut knows that the Moon has a density pof 3340 kg/m³ and a radius Rof 1740 km. (a) Show with (1) that the potential energy of the rock at height h above the surface is given by: 4TG E 3 R+h (2) (b) Next, show that the gravitational constant can be determined by: G-(1-) 3 v? R (3) 8n pR? R+h (c) What is the resulting G if the rock is thrown with 30 km/h and reaches 21.5 m?

An astronaut working on the Moon tries to determine the gravitational constant G by throwing a Moon rock of mass m with a velocity of v vertically into the sky. The astronaut knows that the Moon has a density pof 3340 kg/m³ and a radius Rof 1740 km. (a) Show with (1) that the potential energy of the rock at height h above the surface is given by: 4TG E 3 R+h (2) (b) Next, show that the gravitational constant can be determined by: G-(1-) 3 v? R (3) 8n pR? R+h (c) What is the resulting G if the rock is thrown with 30 km/h and reaches 21.5 m?

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Description: An astronaut working on the Moon tries to determine the gravitational constant G by throwinga Moon rock of mass m with a velocity of v vertically into the sky. The astronaut knows that theMoon has a density pof 3340 kg/m³ and a radius R of 1740 km.(

Principles of Physics: A Calculus-Based Text

5th Edition

ISBN:9781133104261

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter6: Energy Of A System

Section: Chapter Questions

Problem 52P

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