Which statement best explains why running on a track with constant speed at 3 m/s is not work, but climbing a mountain at 1 m/s is work? At constant speed, change is potential energy is finite, but climbing a mountain produces change in the kinetic energy. B At constant speed, change in the kinetic energy is finite, but climbing a mountain produces no change in the potential energy. At constant speed, change in the kinetic energy is zero but climbing a mountain produces change in the potential energy. D At constant speed, change in the potential energy is zero, but climbing a mountain produces change in the kinetic energy. At constant speed, change in the potential energy is finite, but climbing a mountain produces no change in the kinetic energy.

Which statement best explains why running on a track with constant speed at 3 m/s is not work, but climbing a mountain at 1 m/s is work? At constant speed, change is potential energy is finite, but climbing a mountain produces change in the kinetic energy. B At constant speed, change in the kinetic energy is finite, but climbing a mountain produces no change in the potential energy. At constant speed, change in the kinetic energy is zero but climbing a mountain produces change in the potential energy. D At constant speed, change in the potential energy is zero, but climbing a mountain produces change in the kinetic energy. At constant speed, change in the potential energy is finite, but climbing a mountain produces no change in the kinetic energy.

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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

Chapter7: Conservation Of Energy

Section: Chapter Questions

Problem 2CQ

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