2. A curling stone of mass 19 kg, originally at rest, is given a constant push of 4.5 N [E]. The coefficient of kinetic friction between the curling stone and the ice is 0.010. . The push lasts for 1.0 s and then the box is allowed to slide on its own until it comes to rest. Hint free body diagrams in your rough work will help you solve. a. Draw an ID diagram AND a force (FBD) diagram of the stone while the push was being applied. b. Draw a force (FBD) diagram of the stone AFTER the push was removed. c. Determine the force of friction on the stone. d. Determine the acceleration of the stone as it is being pushed. e. Calculate the speed of the stone just as the push stops. f. Determine the acceleration of the stone as it is sliding on its own (with the force no longer applied). g. What distance did the stone travel AFTER the push was removed?

2. A curling stone of mass 19 kg, originally at rest, is given a constant push of 4.5 N [E]. The coefficient of kinetic friction between the curling stone and the ice is 0.010. . The push lasts for 1.0 s and then the box is allowed to slide on its own until it comes to rest. Hint free body diagrams in your rough work will help you solve. a. Draw an ID diagram AND a force (FBD) diagram of the stone while the push was being applied. b. Draw a force (FBD) diagram of the stone AFTER the push was removed. c. Determine the force of friction on the stone. d. Determine the acceleration of the stone as it is being pushed. e. Calculate the speed of the stone just as the push stops. f. Determine the acceleration of the stone as it is sliding on its own (with the force no longer applied). g. What distance did the stone travel AFTER the push was removed?

Name: Solve all parts with full steps please 2. A curling stone of mass 19 k
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Description: Solve all parts with full steps please 2. A curling stone of mass 19 kg, originally at rest, is given a constant push of 4.5 N [E]. The coefficient of kineticfriction between the curling stone and the ice is 0.010.. The push lasts for 1.0 s and then

College Physics

10th Edition

ISBN:9781285737027

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter4: The Laws Of Motion

Section: Chapter Questions

Problem 42P: A block of mass 3m is placed on a frictionless horizontal surface, and a second block of mass m is...

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