Shown in the figure below is a set of two masses on a track. There is no friction in this problem. The small mass, m = 1.25 kg, is initially stationary at a height of y1 = 0.86 meters. The large mass, M = 4.30 kg, is stationary on the flat surface. The following sequence of events occur: 1 → 2 : The small mass slides down the ramp. 2 → 3 : The small and large mass collide elastically. 3 → 4 : The small and large mass recede from each other after the elastic collision. Determine all the following: The velocity of the small mass before the collision: v2 = m/s The velocity of the small mass after the collision: v3 = m/s The velocity of the large mass after the collision: V3 = m/s
Shown in the figure below is a set of two masses on a track. There is no friction in this problem. The small mass, m = 1.25 kg, is initially stationary at a height of y1 = 0.86 meters. The large mass, M = 4.30 kg, is stationary on the flat surface. The following sequence of events occur: 1 → 2 : The small mass slides down the ramp. 2 → 3 : The small and large mass collide elastically. 3 → 4 : The small and large mass recede from each other after the elastic collision. Determine all the following: The velocity of the small mass before the collision: v2 = m/s The velocity of the small mass after the collision: v3 = m/s The velocity of the large mass after the collision: V3 = m/s
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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Shown in the figure below is a set of two masses on a track. There is no friction in this problem. The small mass, m = 1.25 kg, is initially stationary at a height of y1 = 0.86 meters. The large mass, M = 4.30 kg, is stationary on the flat surface.
The following sequence of events occur:
-
1 → 2 :The small mass slides down the ramp.
-
2 → 3 :The small and large mass collide elastically.
-
3 → 4 :The small and large mass recede from each other after the elastic collision.
Determine all the following:
The velocity of the small mass before the collision: v2 = m/s
The velocity of the small mass after the collision: v3 = m/s
The velocity of the large mass after the collision: V3 = m/s
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