Keep the track tilted at 13∘∘ with the horizontal. Put the friction block on the track surface at the top of the track. Let the friction block slide downwards. The length of the track is 74 cm. Starting from zero speed at the top of the track, what will be the speed of the friction block as it reaches the bottom? Write your answer in m/s. Use μμk = 0.13 and mass of the friction block = 400 grams.

Keep the track tilted at 13∘∘ with the horizontal. Put the friction block on the track surface at the top of the track. Let the friction block slide downwards. The length of the track is 74 cm. Starting from zero speed at the top of the track, what will be the speed of the friction block as it reaches the bottom? Write your answer in m/s. Use μμk = 0.13 and mass of the friction block = 400 grams.

Name: Keep the track tilted at 13∘∘ with the horizontal. Put the friction bl
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Description: Keep the track tilted at 13∘∘ with the horizontal. Put the friction block on the track surface at the top of the track. Let the friction block slide downwards. The length of the track is 74 cm. Starting from zero speed at the top of the track, what w

Physics for Scientists and Engineers: Foundations and Connections

1st Edition

ISBN:9781133939146

Author:Katz, Debora M.

Publisher:Katz, Debora M.

Chapter20: Kinetic Theory Of Gases

Section: Chapter Questions

Problem 5PQ

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