Solved

An Object of Mass M Is Moving with Velocity V

Question 36

Multiple Choice

An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3
An object of mass M is moving with velocity V An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 + An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 ) , v(2 An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 - An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 ) , and v(2 An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 - 2 An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is


A) 15V An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 /18 + V An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 /9
B) 23V An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 /18 + V An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 /9
C) 13V An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 /6 + V An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 /3
D) 13V An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 /18 + V An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 /9
E) 23V An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 /18 + V An object of mass M is moving with velocity V . Three smaller objects each of mass m are initially at rest. After the collision the small masses have velocities given by v( + ) , v(2 - ) , and v(2 - 2 ) . If m = M/6 and v = V/3, then the final vector velocity of the mass M is A) 15V /18 + V /9 B) 23V /18 + V /9 C) 13V /6 + V /3 D) 13V /18 + V /9 E) 23V /18 + V /3 /3

Correct Answer:

verifed

Verified

Unlock this answer now
Get Access to more Verified Answers free of charge

Related Questions

Q15: A pitcher throws a baseball with a

Q24: Instead of a ballistic pendulum we

Q25: If a body moves in such a

Q31: The force exerted on a body of

Q37: <img src="https://d2lvgg3v3hfg70.cloudfront.net/TB6080/.jpg" alt=" A 4.0-kg block,

Q39: <img src="https://d2lvgg3v3hfg70.cloudfront.net/TB6080/.jpg" alt=" The balls shown

Q45: The condition necessary for the Conservation of

Q48: Two identical cars approach an intersection.One is

Q61: In a real collision,<br>A)kinetic energy is conserved.<br>B)linear

Q81: Two equal masses travel in opposite directions