The figure shows block 1 of mass 0.265 kg sliding to the right over a frictionless...
Figure 15-34 shows block 1 of mass 0.200 kg sliding to the right over a frictionless elevated surface at a speed of 8.00 m/s. The block undergoes an elastie collision with stationary block 2, which is attached to a spring of spring constant 1208.5 N/m. (Assume that the spring does not affect the collision.) After the collision, block 2 oscillates in SHM with a period of 0.140 s, and block 1 slides off the opposite end of the elevated sturface,...
HESSME HY INSTRUCTOR FULL SCREEN PRINTER VERSION BACK NEXT T RESOURCES Assignment 1 Question 3 The figure shows block 1 of mass 0.200 kg sliding to the right over a frictionless elevated surface at a speed of 8.30 m/s. The block undergoes an elastic collision with stationary black 2, which is attached to a spring of spring constant 1105 N/m. (Assume that the spring does not affect the collision.) After the collision, block 2 oscillates in SHM with a period...
In the figure puck 1 of mass m_1 = 1.1 kg is sent sliding across a frictionless lab bench, to undergo a one-dimensional elastic collision with stationary puck 2. Puck 2 then slides off the bench and lands a distance d from the base of the bench. Puck 1 rebounds from the collision and slides off the opposite edge of the bench, landing a distance 6d from the base of the bench. What is the mass of puck 2?
Block A of a mass 0.7 kg is sliding to the right at a speed of 4.7 m/s while block B of mass 4.5kg is sliding to the right with a velocity of 1.2 m/s. The surface is frictionless for both blocks. If they collide perfectly elastically what is the speed of block A after the collision?
In the figure, block 2 of mass 2.60 kg oscillates on the end of a spring in SHM with a period of 24.00 ms. The position of the block is given by x = (1.60 cm) cos(wt + pi/2). Block 1 of mass 5.20 kg slides toward block 2 with a velocity of magnitude 7.20 m/s, directed along the spring's length. The two blocks undergo a completely inelastic collision at time t = 6.00 ms. (The duration of the collision...
In the figure, block 2 of mass 2.60 kg oscillates on the end of a spring in SHM with a period of 26.00 ms. The position of the block is given by x = (1.50 cm) cos(ωt + π/2). Block 1 of mass 5.20 kg slides toward block 2 with a velocity of magnitude 3.00 m/s, directed along the spring's length. The two blocks undergo a completely inelastic collision at time t= 6.50 ms. (The duration of the collision is...
A block with mass M = 5.95 kg is sliding in the positive x-direction at Vi = 8.90 m/s on a frictionless surface when it collides elastically in one dimension with a stationary block with mass m = 1.30 kg. Determine the velocities, Vf and vf, of the objects after the collision.
A block of mass 7.8kg is sliding over a frictionless surface, toward the right, at an initial speed of 14m/sec. Let the x-axis point toward the right. Compute its initial momentum, P0, and record its momentum in the space provided: a) P0 = ________ i + ________ j b) The block collides with a wall, and afterwards is moving at 14m/sec toward the LEFT. (This is a “perfectly elastic collision”, BTW). Record its momentum after the collision, P1, in the...
In the figure, block 1 of mass 2.00 kg slides from rest along a frictionless ramp from height h = 2.60 m and then collides with stationary block 2, which has mass 4.50 kg. The spring shown has a spring constant of 31.5 N/m. (a) How fast is block 1 moving just before contacting block 2? (b) Assume the whole path is frictionless, and the collision is completely inelastic, how far does the spring compress? (c) Now, assume you test...
Question 12 In the figure, block 2 of mass 2.20 kg oscillates on the end of a spring in SHM with a period of 14.00 ms. The position of the block is given by x = (1.40 cm) cos(wt + x/2). Block 1 of mass 4.40 kg slides toward block 2 with a velocity of magnitude 8.40 m/s, directed along the spring's length. The two blocks undergo a completely inelastic collision at time t = 3.50 ms. (The duration of...