A person with m1 = m runs at a velocity of v1 = u, jumping to a platform with a mass of m2 = 1.5m and moving at a velocity of v2 = 2u. What will be the speed of the platform after jumping to the platform?
A block of mass m1 = 1.10 kg moving at v1 = 1.20 m/s undergoes a completely inelastic collision with a stationary block of mass m2 = 0.900 kg . The blocks then move, stuck together, at speed v2. After a short time, the two-block system collides inelastically with a third block, of mass m3 = 2.40 kg , which is initially at rest. The three blocks then move, stuck together, with speed v3. Assume that the blocks slide without...
A block of mass m1 = 1.10 kg moving at v1 = 1.20 m/s undergoes a completely inelastic collision with a stationary block of mass m2 = 0.900 kg . The blocks then move, stuck together, at speed v2. After a short time, the two-block system collides inelastically with a third block, of mass m3 = 2.40 kg , which is initially at rest. The three blocks then move, stuck together, with speed v3. Assume that the blocks slide without...
A block of mass m1 = 1.70 kg moving at v1 = 2.00 m/sundergoes a completely inelastic collision with a stationary block of mass m2 = 0.300 kg . The blocks then move, stuck together, at speed v2. After a short time, the two-block system collides inelastically with a third block, of mass m3 = 2.40 kg , which is initially at rest. The three blocks then move, stuck together, with speed v3.(Figure 1) Assume that the blocks slide without...
A mass m1 moving at a velocity of v1 collides elastically with a mass m2 which is initially at rest. a. what fraction of the original kinetic energy does mass 1 retain after the collision? Give your answer in terms of the masses. (Hint: Find the ratio of Kafter/Kbefore for the first mass) b. a mass m1 is placed on a frictionless ramp at a height of h. It is then released and slides down without rolling to elastically collide...
A block of mass m1 = 1.60kg moving at v1 =
2.00m/s undergoes a completely inelastic collision with a stationary
block of mass m2 = 0.100kg . The blocks then move, stuck
together, at speed v2. After a short time, the two-block
system collides inelastically with a third block, of massm3 = 2.70kg , which is initially at rest. The three blocks
then move, stuck together, with speed v3.(Figure 1) Assume that the
blocks slide without friction.Part AFind v2v1, the...
A block of mass m1 moving with speed v1 undergoes a completely inelastic collision with a stationary block of mass m2. The blocks then move, stuck together, at speed v2. After a short time, the two-block system collides inelastically with a third block, of mass m3, which is initially stationary. The three blocks then move, stuck together, with speed v3 (Figure 1) . All three blocks have nonzero mass. Assume that the blocks slide without friction.
A block of mass m1 = 1.4 kg initially moving to the right with a speed of 3.0 m/s on a frictionless, horizontal track collides with a spring attached to a second block of mass m2 = 2.5 kg initially moving to the left with a speed of 1.8 m/s. The spring constant is 565N/m. What if m1 is initially moving at 3.2 m/s while m2 is initially at rest? (a) Find the maximum spring compression in this case. (b)...
An atom of mass m1 = m moving in the x direction with speed v1 = v collides elastically with an atom of mass m2 = 4m at rest. After the collision the first atom moves in the y direction. Find the direction of motion of the second atom. _______ ° counterclockwise from the +x-axis Find the speeds of both atoms (in terms of v) after the collision. v'1 =_____ v v'2 =______ v
Two objects with masses represented by m1 and m2 are moving such that their combined total momentum has a magnitude of 18.5 kg · m/s and points in a direction 71.5°above the positive x-axis. Object m1 is moving in the x direction with a speed of v1 = 2.75 m/s and m2 is moving in the y direction with a speed of v2 = 3.22 m/s. Determine the mass of each object in kilograms. m1= kg m2= kg
Two particles are moving along the x axis. Particle 1 has a mass m1 and a velocity v1 = +4.5 m/s. Particle 2 has a mass m2 and a velocity v2 = -7.3 m/s. The velocity of the center of mass of these two particles is zero. In other words, the center of mass of the particles remains stationary, even though each particle is moving. Find the ratio m1/m2 of the masses of the particles.