2. A pendulum bob, m,, of mass 0.300 kg is held at a vertical height of 0.400 m above the bottom of its swing. It is then released and swings down. Just as it passes through its lowest point in the swing it hits a block, m, of mass 0.0500 kg. On collision m, transfers 20. 0% of its total energy to m2. m, then slides for 1.00 m along a flat surface where the coefficient of friction between m, and the surface is 0.100. Determine: I a) The speed of m1 just before hitting m2. b) The total energy of m2 right after it was hit by m1. c) The total energy of m2 at the bottom of the ramp

2. A pendulum bob, m,, of mass 0.300 kg is held at a vertical height of 0.400 m above the bottom of its swing. It is then released and swings down. Just as it passes through its lowest point in the swing it hits a block, m, of mass 0.0500 kg. On collision m, transfers 20. 0% of its total energy to m2. m, then slides for 1.00 m along a flat surface where the coefficient of friction between m, and the surface is 0.100. Determine: I a) The speed of m1 just before hitting m2. b) The total energy of m2 right after it was hit by m1. c) The total energy of m2 at the bottom of the ramp

Name: Please show full calculation formulas 2. A pendulum bob, m,, of mass 0
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Description: Please show full calculation formulas 2. A pendulum bob, m,, of mass 0.300 kg is held at a vertical height of 0.400 m above thebottom of its swing. It is then released and swings down. Just as it passes through its lowestpoint in the swing it hits a

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

Chapter8: Momentum And Collisions

Section: Chapter Questions

Problem 29P: A billiard ball moving at 5.00 m/s strikes a stationary ball of the same mass. After the collision,...

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