In this problem, we will consider the following situation as depicted in the diagram: A block of mass m slides at a speed v along a horizontal smooth table. It next slides down a smooth ramp, descending a height h, and then slides along a horizontal rough floor, stopping eventually. Assume that the block slides slowly enough so that it does not lose contact with the supporting surfaces (table, ramp, or floor). You will analyze the motion of the block at different moments using the law of conservation of energy. A B y=0 C a. Which word in the statement of this problem allows you to assume that the table is frictionless? b. Where (letter) would the block have the greatest gravitational potential energy? c. Where (location) would the block experience the greatest kinetic energy?
In this problem, we will consider the following situation as depicted in the diagram: A block of mass m slides at a speed v along a horizontal smooth table. It next slides down a smooth ramp, descending a height h, and then slides along a horizontal rough floor, stopping eventually. Assume that the block slides slowly enough so that it does not lose contact with the supporting surfaces (table, ramp, or floor). You will analyze the motion of the block at different moments using the law of conservation of energy. A B y=0 C a. Which word in the statement of this problem allows you to assume that the table is frictionless? b. Where (letter) would the block have the greatest gravitational potential energy? c. Where (location) would the block experience the greatest kinetic energy?
College Physics
11th Edition
ISBN:9781305952300
Author:Raymond A. Serway, Chris Vuille
Publisher:Raymond A. Serway, Chris Vuille
Chapter1: Units, Trigonometry. And Vectors
Section: Chapter Questions
Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...
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Transcribed Image Text:In this problem, we will consider the following situation as depicted in the diagram: A block of mass m
slides at a speed v along a horizontal smooth table. It next slides down a smooth ramp, descending a
height h, and then slides along a horizontal rough floor, stopping eventually. Assume that the block
slides slowly enough so that it does not lose contact with the supporting surfaces (table, ramp, or
floor). You will analyze the motion of the block at different moments using the law of conservation of
energy.
A
B
y=0
C
a. Which word in the statement of this problem allows you to assume that the table is
frictionless?
b. Where (letter) would the block have the greatest gravitational potential energy?
c. Where (location) would the block experience the greatest kinetic energy?
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