The two blocks in the figure are at rest on frictionless surfaces.
What must be the mass of the right block in order that the two blocks remain stationary?
The two blocks in the figure are at rest on frictionless surfaces. What must be the...
In Figure (1), a 3.50 g bullet is fired horizontally at two
blocks at rest on a frictionless table. The bullet passes through
block 1 (mass 1.20 kg) and embeds itself in block 2 (mass 1.85 kg).
The blocks end up with speeds v1 = 0.510 m/s and v2 = 1.38 m/s (see
Figure (2)). Neglecting the material removed from block 1 by the
bullet, find the speed of the bullet as it (a) leaves and (b)
enters block 1....
In Figure (1), a 3.50 g bullet is fired horizontally at two
blocks at rest on a frictionless table. The bullet passes through
block 1 (mass 1.04 kg) and embeds itself in block 2 (mass 1.69 kg).
The blocks end up with speeds v1 = 0.550 m/s and v2 = 1.40 m/s (see
Figure (2)). Neglecting the material removed from block 1 by the
bullet, find the speed of the bullet as it (a) leaves and (b)
enters block 1....
In Figure (1), a 3.50 g bullet is fired horizontally at two blocks at rest on a frictionless table. The bullet passes through block 1 (mass 1.13 kg) and embeds itself in block 2 (mass 1.65 kg). The blocks end up with speeds V1 = 0.550 m/s and v2 = 1.45 m/s (see Figure (2)). Neglecting the material removed from block 1 by the bullet, find the speed of the bullet as it (a) leaves and (b) enters block 1....
In Figure (1), a 3.50 g bullet is fired horizontally at two blocks at rest on a frictionless table. The bullet passes through block 1 (mass 1.33 kg) and embeds itself in block 2 (mass 1.89 kg). The blocks end up with speeds V1 = 0.560 m/s and v2 = 1.42 m/s (see Figure (2)). Neglecting the material removed from block 1 by the bullet, find the speed of the bullet as it (a) leaves and (b) enters block 1....
In Figure (1), a 3.50 g bullet is fired horizontally at two
blocks at rest on a frictionless table. The bullet passes through
block 1 (mass 1.36 kg) and embeds itself in block 2 (mass 1.87 kg).
The blocks end up with speeds v1 = 0.500 m/s and v2 = 1.35 m/s (see
Figure (2)). Neglecting the material removed from block 1 by the
bullet, find the speed of the bullet as it (a)
leaves and (b) enters block 1.
Two blocks are on a frictionless surface. One block is at rest and the other collides with it at 25 m/s in the +x-direction. Both blocks have the same mass. The first block flies off at +45-degrees to the +x-axis and the other flies off at -45-degrees to the +x-axis. What is the magnitude of the velocity of the two pucks? Assume that this is an elastic collision. Draw a diagram to support your answer.
two blocks are positioned on surfaces, each inclined at the same angle of 49.4 degrees with respect to the horizontal. The blocks are connected by a rope which rests on a frictionless pulley at the top of the inclines as shown, so the blocks can slide together. The mass of the black block is 4.61 kg, and the coefficient of kinetic friction for both blocks and inclines is 0.470. Assume static friction has been overcome and that everything can slide....
In Figure (1), a 3.50 g bullet is fired horizontally at two blocks at rest on a frictionless table. The bullet passes through block 1 (mass 1.37 kg) and embeds itself in block 2 (mass 2.01 kg). The blocks end up with speeds v_1 = 0.600 m/s and v_2 = 1.45 m/s (see Figure (2)). Neglecting the material removed from block 1 by the bullet, find the speed of the bullet as it (a) leaves and (b) enters block 1....
The figure shows a two-ended “rocket” that is initially
stationary on a frictionless floor, with its center at the origin
of an x axis. The rocket consists of a central block C (of mass M = 6.70 kg) and blocks L and R (each of mass m = 1.50 kg) on the left and
right sides. Small explosions can shoot either of the side blocks
away from block C and along the x axis. Here is
the sequence: (1) At time t =...
The figure shows a two-ended “rocket” that is initially stationary on a frictionless floor, with its center at the origin of an x axis. The rocket consists of a central block C (of mass M = 6.10 kg) and blocks L and R (each of mass m = 2.70 kg) on the left and right sides. Small explosions can shoot either of the side blocks away from block C and along the x axis. Here is the sequence: (1) At...