ㅁ 6. A large block 10-kg in mass sits on a horizontal surface. A smaller block 2-kg in mass is placed next to the larger block, as shown below. The coefficient of static friction between the blocks is 0.25; all other surfaces are frictionless. Note that the tendency of the system is for the 2-kg mass to want to slide downwards due to gravity. To try to counteract this, you push on the 2-kg block with a force F which causes it to interact with the 10-kg mass. a. What minimum force must be applied to the system to keep the 2-kg mass from sliding down the side of the 10-kg mass? b. If this force is applied, what is the acceleration of the small block? C. d. What force (direction and magnitude) does the small block exert on the larger block? What force (direction and magnitude) does the large block exert on the small block? H=0.25 F=? 2-kg 10-kg

ㅁ 6. A large block 10-kg in mass sits on a horizontal surface. A smaller block 2-kg in mass is placed next to the larger block, as shown below. The coefficient of static friction between the blocks is 0.25; all other surfaces are frictionless. Note that the tendency of the system is for the 2-kg mass to want to slide downwards due to gravity. To try to counteract this, you push on the 2-kg block with a force F which causes it to interact with the 10-kg mass. a. What minimum force must be applied to the system to keep the 2-kg mass from sliding down the side of the 10-kg mass? b. If this force is applied, what is the acceleration of the small block? C. d. What force (direction and magnitude) does the small block exert on the larger block? What force (direction and magnitude) does the large block exert on the small block? H=0.25 F=? 2-kg 10-kg

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 13WUE: A block of mass m1= 10 kg is on a frictionless table to the left of a second block of mass m2 = 24...

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