017 10.0 points Two masses undergo a front-to-back collision. The masses are mı = m, with...
Two particles of mass m1 = 2.0 kg and m2 = 2.6 kg undergo a one-dimensional head-on collision as shown in the figure below. Their initial velocities along x are vii = 15 m/s and v2,--6.8 m/s. The two particles stick together after the collision (a completely inelastic collision. (Assume to the right as the positive direction.) mi m2 (a) Find the velocity after the collision. 2.6782 m/s (b) How much kinetic energy is lost in the collision? 153.907x
Consider two masses sliding across a frictionless surface about to undergo a head-on collision as shown in the figure. The first mass (m1 =3 kg) is travelling to the right with a speed of v1 = 8 m/s. The speed of the second mass (m2 = 5 kg) is unknown. After the masses collide, ma rebounds moving off at a speed of v = 2 m/s in the opposite direction, while mz is motionless. a)(10 pts.) At what velocity, v2...
Consider two masses sliding across a frictionless surface about to undergo a head-on collision as shown in the figure. The first mass (m1 = 3 kg) is travelling to the right with a speed of V1 = 8 m/s. The speed of the second mass (m2 = 5 kg) is unknown. After the masses collide, m1 rebounds moving off at a speed of v = 2 m/s in the opposite direction, while m2 is motionless. a)(10 pts.) At what velocity,...
4. Consider two asteroids with masses mi and m2 located in outer space far away from any external forces. m2 is initially stationary but mi travels horizontally to the right towards m2 with an initial speed vo. Let's assume that after the collision the asteroids only move horizontally (in other words we'll assume this problem is purely 1-dimensional) a) Suppose the asteroids stick together after colliding. Find an expression for the final velocity of the asteroids and show that the...
The figure below show three masses m1=1.1 kg, m2=2.8 kg, and
m3=4.3 kg which undergo two successive collisions. The first
collision between m1, which has an initial velocity v=8.2 m/s, and
m2 (which is initially at rest) is completely inelastic. The second
collision between the combined mass m1+m2 and m3 (which is
initially at rest) is elastic. What is the velocity of m3 after the
second collision?
The figure below show three masses m1=1.1 kg, m2=2.8 kg, and m3=4.3 kg...
The figure below show three masses m1=1.7 kg, m2=2.9 kg, and
m3=4.5 kg which undergo two successive collisions. The first
collision between m1, which has an initial velocity v=7.9 m/s, and
m2 (which is initially at rest) is completely inelastic. The second
collision between the combined mass m1+m2 and m3 (which is
initially at rest) is elastic. What is the velocity of m3 after the
second collision? (use figure in picture, but answer question
above)
The figure below show three...
The figure below show three masses m=1.1 kg, m2=2.6 kg, and m3=4.1 kg which undergo two successive collisions. The first collision between my, which has an initial velocity v=6.2 m/s, and m2 (which is initially at rest) is completely inelastic. The second collision between the combined mass m +m2 and m3 (which is initially at rest) is elastic. What is the velocity of mz after the second collision? 1 2 3 Select one 2.97 m/s 1.92 m/s 1.22 m/s 2.27...
The figure below show three masses m=1.6 kg, m2=3.0 kg, and m3=4.6 kg which undergo two successive collisions. The first collision between mi, which has an initial velocity v=6.9 m/s, and m2 (which is initially at rest) is completely inelastic. The second collision between the combined mass mi+m2 and m3 (which is initially at rest) is elastic. What is the velocity of mg after the second collision? V 2 3 Select one 04.08 m/s O 2.40 m/s 2.64 m/s O...
The
figure below show three masses m1=1.6 kg, m2=3.0 kg, and m3=4.6 kg
which undergo two successive collisions. The first collision
between m1, which has an initial velocity v=6.9 m/s, and m2 (which
is initially at rest) is completely inelastic. The second collision
between the combined mass m1+m2 and m3 (which is initially at rest)
is elastic. What is the velocity of m3 after the second
collision?
V 1 2 co
The figure below show three masses m1=1.5 kg,
m2=2.7 kg, and m3=4.6 kg which undergo two
successive collisions. The first collision between m1,
which has an initial velocity v=8.6 m/s, and m2 (which
is initially at rest) is completely inelastic. The second collision
between the combined mass m1+m2 and
m3 (which is initially at rest) is elastic. What is the
velocity of m3 after the second collision?
V 1 2 co