A skater of mass 60.0 kg standing on ice throws a stone of mass 7.69 kg...

This 80 kg ice skater moving at 2.5 m/s throws a 200 g puck in the...

This 80 kg ice skater moving at 2.5 m/s throws a 200 g puck in the direction he is moving at 15 m/s relative to the ice. a. Find the velocity of the ice skater after throwing the puck. (Ignore friction) b. A second skater who is 60 kg initially at rest catches the puck. Find the velocity of the second skater after catching the puck.

A 60.0 kg skater moving initially at 3.15 m/s on rough horizontal ice comes to rest...

A 60.0 kg skater moving initially at 3.15 m/s on rough horizontal ice comes to rest uniformly in 3.85 s due to friction from the ice. What force does friction exert on the skater? F= Value? units?

A 62 kg ice skater moving at 3.2 m/s collides with a second stationary skater with...

A 62 kg ice skater moving at 3.2 m/s collides with a second stationary skater with mass 65 kg. The skaters cling together after the collision and move without friction. Compute their speed after the collision.

07.2 Skater A, with mass 80 kg and initial speed 9.0 m/s, runs into stationary Skater...

07.2 Skater A, with mass 80 kg and initial speed 9.0 m/s, runs into stationary Skater B, mass 65 kg. After the collision, Skater A moves at an angle of 55.0o from her original direction and Skater B moves at an angle of 10o from Skater A’s original direction. Both skaters move on the frictionless, horizontal surface of the rink. (a) What are the final speeds of Skater A and Skater B. (b) Is kinetic energy conserved? If not, what...

A 55 kg ice skater is gliding along at 3.5 m/s. 5 seconds later her speed...

A 55 kg ice skater is gliding along at 3.5 m/s. 5 seconds later her speed has dropped to 2.9 m/s. a) What is the magnitude of the kinetic friction acting on her skates? Ignore!ofair. b) What is the coefficient of friction between the metal skate blade and the ice?

Can you solve it please Question 1: A. A m1 = 80 kg ice skater moving...

Can you solve it please Question 1: A. A m1 = 80 kg ice skater moving at 50.4 km/h due North crashes into a stationary skater of equal mass. After the collision, the two skaters move as one body at 6 m/s due North. If the collision lasts for 2.0 milliseconds, use the impulse – momentum theorem to find: i. The impulse delivered to the m1 skater due to the collision. ii. The magnitude of the average force exerted on...

During an ice show a 55.0 kg skater leaps into the air and is caught by...

During an ice show a 55.0 kg skater leaps into the air and is caught by an initially stationary 90.0 kg skater. (a) What is their final velocity in meters per second assuming negligible friction and that the 55.0-kg skater's original horizontal velocity was 4.00 m/s? ________ m/s (b) How much kinetic energy is lost in joules? _______J

1`A puck of mass 0.110 kg slides across ice in the positive x-direction with a kinetic...

1`A puck of mass 0.110 kg slides across ice in the positive x-direction with a kinetic friction coefficient between the ice and puck of 0.167. If the puck is moving at an initial speed of 15.0 m/s, find the following. (a) What is the force of kinetic friction? (Indicate the direction with the sign of your answer.) N (b) What is the acceleration of the puck? (Indicate the direction with the sign of your answer.) m/s2 (c) How long does...

A child with a mass of 50 kg is standing at the edge of a merry-go-round...

A child with a mass of 50 kg is standing at the edge of a merry-go-round which has a radius of 3.50 m and a mass of 700 kg. The merry-go-around is initially at rest. The child throws a 1.20 kg stone perpendicular to the merry-go-round's radius at a speed of 6.0 m/s. What is the resulting angular speed of the entire system? Friction is negligible and the merry-go-round is a uniform disk. The child is classified as a point...

An ice-skaters of mass 70 kg is moving to the right with a speed of 20...

An ice-skaters of mass 70 kg is moving to the right with a speed of 20 m/s. She bumped into a 62kg ice-skater moving in opposite direction at 13 m/s. Both hold on to each other after the collision. Determine: A) Their final velocity B) the fraction of the initial energy lost