A block of unknown mass is placed on a ramp at a height h above the ground as shown. The block is given a push so it has an initial velocity of v0. The block travels down the ramp, which is frictionless; upon reaching the bottom, the block travels along the horizontal surface where friction is present. The coefficient of friction is mu. How far along the horizontal surface does the mass travel before coming to a stop? A. (1/2 v0^2 + g h) / [sqrt(mu) g] B. (1/2 v0^2 + g h) mu / g C. (1/2 v0^2 + g h) / mu g D. (1/2 v0^2 + g h) sqrt(mu) / g E. cannot be determined without knowing the mass value
A block of unknown mass is placed on a ramp at a height h above the ground as shown. The block is given a push so it has an initial velocity of v0. The block travels down the ramp, which is frictionless; upon reaching the bottom, the block travels along the horizontal surface where friction is present. The coefficient of friction is mu. How far along the horizontal surface does the mass travel before coming to a stop? A. (1/2 v0^2 + g h) / [sqrt(mu) g] B. (1/2 v0^2 + g h) mu / g C. (1/2 v0^2 + g h) / mu g D. (1/2 v0^2 + g h) sqrt(mu) / g E. cannot be determined without knowing the mass value
Physics for Scientists and Engineers, Technology Update (No access codes included)
9th Edition
ISBN:9781305116399
Author:Raymond A. Serway, John W. Jewett
Publisher:Raymond A. Serway, John W. Jewett
Chapter8: Conservation Of Energy
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Problem 8.21P: A toy cannon uses a spring to project a 5.30-g soft rubber ball. The spring is originally compressed...
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A block of unknown mass is placed on a ramp at a height h above the ground as shown. The block is given a push so it has an initial velocity of v0. The block travels down the ramp, which is frictionless; upon reaching the bottom, the block travels along the horizontal surface where friction is present. The coefficient of friction is mu. How far along the horizontal surface does the mass travel before coming to a stop?
A. (1/2 v0^2 + g h) / [sqrt(mu) g]
B. (1/2 v0^2 + g h) mu / g
C. (1/2 v0^2 + g h) / mu g
D. (1/2 v0^2 + g h) sqrt(mu) / g
E. cannot be determined without knowing the mass value
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