Puck A (mA = 2kg) moving at 5m/s along Ox collides with puck B(mB = 3kg)...

a 1.50 kg " particle A" travelling with velocity ua= 0.8im/s collides with a 3.60 kg...

a 1.50 kg " particle A" travelling with velocity ua= 0.8im/s collides with a 3.60 kg with velocity ub = 2.2j m/s . there is a short collision that lasts 0.5 seconds after the two particles stick to each other and move together . Find their velocities in unit vector notation while they move together find the average force in unit vector notation on particle A during collision time Draw a clear digram and show Ox and Oy axes plz...

In a particular crash test, an automobile of mass 1542 kg collides with a wall and...

In a particular crash test, an automobile of mass 1542 kg collides with a wall and bounces back off the wall. The x components of the initial and final speeds of the automobile are 22 m/s and 1.7 m/s, respectively. 1) If the collision lasts for 0.1 s, find the magnitude of the impulse due to the collision. Answer in units of kg · m/s. 2) Calculate the magnitude of the average force exerted on the automobile during the collision....

2.00-kg block A traveling east at 20.0 m/s collides with 3.00-kg block B traveling west at...

2.00-kg block A traveling east at 20.0 m/s collides with 3.00-kg block B traveling west at 10.0 m/s. After the collision, block A has a velocity of 5.00 m/s due west. (a) How much kinetic energy was lost during the collision? (b) If the blocks were in contact for 75 ms, determine the magnitude and direction of average force exerted on block A.

A 2.50 kg mass moving 7.50 m/s to the right collides head on with a 4.90...

A 2.50 kg mass moving 7.50 m/s to the right collides head on with a 4.90 kg mass. After the collision the 2.50 kg mass is moving 5.00 m/s to the left and the 4.90 kg mass is moving 4.88 m/s to the right. a. Calculate the velocity of the 4.90 kg mass before the collision b. If the collision lasts for 0.0625 seconds calculate the force that acted on each mass during the collision.

Two balls moving with the same speed of v = 0.48 m/s but in opposite directions...

Two balls moving with the same speed of v = 0.48 m/s but in opposite directions undergo a head-on collision. Ball A has mass mA = 2.6 kg and is traveling to the left, while ball B has mass mB = 1.3 kg and is traveling to the right. The balls are shown just before the collision in the figure below. (a) Which ball has the larger momentum (in magnitude) before the collision? Ball A Ball B Both balls have...

A car having mass M1= 1000 Kg moving initially at V1i= 60 m/s collides with a...

A car having mass M1= 1000 Kg moving initially at V1i= 60 m/s collides with a car having mass M2= 3000 Kg that was moving initially at V2i = 20m/s. After the inelastic collision, the cars stick and move together. The final velocity of the two cars just after collision is Vf  =_______ m/s Part A 40 20 60 30 Part B If the collision time is t = 0.25 seconds, the force exerted on the car having mass M2= 3000...

A solid steel ball moving at a speed of 4.20m/s collides with another identical ball that...

A solid steel ball moving at a speed of 4.20m/s collides with another identical ball that is stationary, and neither ball is spinning prior to the collision. The balls are magnetized and stick together after the collision. The balls just barely collide, and therefore spin as they continue off together. There is no net force on either of the balls (other than what they exert on each other) before, during, or after the collision. a. find the linear speed of...

Two parts: a) An X1=20 kg mass, moving with an initial velocity vx,i,1=5m/s collides elastically in...

Two parts: a) An X1=20 kg mass, moving with an initial velocity vx,i,1=5m/s collides elastically in one-dimension with an X2=30 kg mass, moving with an initial velocity vx,i,2=7m/s. Determine the final velocities of the two masses, after the collision (remember to keep track of positive vs. negative velocities!). Verify your answer using conservation of KE. b) (the inverse of the inelastic collision problem, and similar to the Hunter Thompson problem from class): An 20 kg mass, on the ground, fires...

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...

When jumping straight down, you can be seriously injured if you land stiff-legged. One way to...

When jumping straight down, you can be seriously injured if you land stiff-legged. One way to avoid injury is to bend your knees upon landing to reduce the force of the impact. A 73.2-kg man just before contact with the ground has a speed of 3.19 m/s. (a) In a stiff-legged landing he comes to a halt in 4.74 ms. Find the magnitude of the average net force that acts on him during this time. (b) When he bends his...