A contestant in a winter sporting event pushes an mm kg block of ice across a frozen lake by applying a force FF at an angle θθ below the horizontal as shown. Assume that the coefficient of static friction for ice on ice is 0.0300, and the coefficient of kinetic friction for the same is 0.0100. Let to the right be the positive x direction and up be the positive y direction for your equations.

Obtain a numeric value, in newtons, for the magnitude of the maximum applied force, F, consistent with static friction when the force makes an angle 32° below the horizontal and the mass of the block is 63 kg. 

Obtain a numeric value for the acceleration, a, in meters per squared seconds, when the mass of the block is 63 kg and the angle of the rope is 32° below the horizontal.

Transcribed Image Text:

The image depicts a person pushing a large ice block. The individual is leaning forward, applying a force (\( \vec{F} \)) at an angle (\( \theta \)) with respect to the horizontal plane. The force vector is represented by a red arrow, illustrating the direction of the applied force, which is downward and forward towards the ice block. The angle (\( \theta \)) formed between the direction of the force and the horizontal is marked with a dashed line parallel to the surface, indicating the breakdown of forces in physics problems. This setup is often used to illustrate concepts in physics related to friction, force components, and the impact of force angles on effective movement or work done on an object.