Deck 9: Center of Mass and Linear Momentum

A) the center of mass of an object must lie within the object
B) all the mass of an object is actually concentrated at its center of mass
C) the center of mass of an object cannot move if there is zero net force on the object
D) the center of mass of a cylinder must lie on its axis
E) none of the above

A) 1.2 m
B) 20 m
C) 31 m
D) Can't tell because the velocities of the fragments are not given.
E) Can't tell because the coordinates of the highest point are not given.

A) is forward of its original position and moving forward
B) is forward of its original position and moving backward
C) is rearward of its original position and moving forward
D) is rearward of its original position and moving backward
E) is rearward of its original position and not moving

A) it is initially at rest and the external forces sum to zero
B) it is initially at rest and the internal forces sum to zero
C) the sum of the external forces is less than the maximum force of static friction
D) no friction acts internally
E) none of the above

A) on the rim
B) a distance R/2 from the center
C) a distance R/3 from the center
D) a distance 2R/3 from the center
E) at the center

A) 1.3 m/s in the same direction as A
B) 1.3 m/s in the same direction as B
C) 2.7 m/s in the same direction as A
D) 1.0 m/s in the same direction as B
E) 5.0 m/s in the same direction as A

A) 0.25 g
B) 0.50 g
C) 0.67 g
D) 0.75 g
E) 1.0 g

A) A
B) B
C) C
D) D
E) E

A) 0 m, 0 m
B) 1.3 m, 1.7 m
C) 1.4 m, 1.9 m
D) 1.9 m, 2.5 m
E) 1.4 m, 2.5 m

A) 1.0 m
B) 3.3 m
C) 10 m
D) 12 m
E) 17 m

A) a little less than halfway between the Earth's surface and the outer boundary of the atmosphere
B) near the surface of the Earth
C) near the outer boundary of the atmosphere
D) near the center of the Earth
E) none of the above

A) 1, 2, 3
B) 1 and 2 tie, then 3
C) 1, then 2 and 3 tie
D) 3, 2, 1
E) 1, 3, 2

A) 2.9 m
B) 4.0 m
C) 7.1 m
D) 7.9 m
E) 10.4 m

A) the spring is compressed at the time of the observation
B) the spring is not compressed at the time of observation
C) the motion was started with the masses at rest
D) the motion was started with at least one of masses moving
E) the motion was started by compressing the spring

A) 4 m
B) 5 m
C) 6 m
D) 10 m
E) need to know the forces they exert

A) the forces exerted by the particles on each other sum to zero
B) the external forces acting on particles of the system sum to zero
C) the velocity of the center of mass is initially zero
D) the particles are distributed symmetrically around the center of mass
E) the center of mass is at the geometric center of the system

A) The center of mass remains at rest.
B) The net external force is zero.
C) The velocity of the center of mass is a constant.
D) The acceleration of the center of mass is g, downward.
E) None of the above statements are true.

A) is the total internal force and m is the total mass of the system
B) is the total internal force and m is the mass acting on the system
C) is the total external force and m is the total mass of the system
D) is the force of gravity and m is the mass of Earth
E) is the force of gravity and m is the total mass of the system

A) closer to the Earth than to either of the other bodies
B) closer to the Sun than to either of the other bodies
C) closer to Mars than to either of the other bodies
D) at the geometric center of the triangle formed by the three bodies
E) at the center of the line joining the Earth and Mars

A) 1:9
B) 1:3
C) 1:1
D) 3:1
E) 9:1

A) weighs more than P
B) is moving faster than P
C) weighs the same as P
D) is moving slower than P
E) is moving at the same speed as P

A) the force of your foot on the accelerator
B) the force of friction of the road on the tires
C) the force of the engine on the drive shaft
D) the normal force of the road on the tires
E) none of the above

A) 1, 2, 3, 4
B) 2, 3, 4, 1
C) 1, 4, 3, 2
D) 4, 3, 2, 1
E) 2, 4, 3, 1

A) a frame for which the momentum of the incident object is zero
B) a frame for which the momentum of the target object is zero
C) a frame for which the average momentum of the two objects is zero
D) a frame for which the total momentum of the two objects is zero
E) none of the above

A) 16 m/s in the same direction as A
B) 16 m/s in the same direction as B
C) 32 m/s in the same direction as A
D) 12 m/s in the same direction as B
E) 60 m/s in the same direction as A

A) 0 J
B) 0.31 J
C) 0.61 J
D) 0.81 J
E) 1.2 J

A) 98 kg∙m/s
B) 78 kg∙m/s
C) 39 kg∙m/s
D) 24 kg∙m/s
E) 0 kg∙m/s

A) 8.0 m/s
B) 21 m/s
C) 49 m/s
D) 64 m/s
E) 65 m/s

A) inertia
B) mass
C) speed
D) velocity
E) acceleration

A) displacement
B) velocity
C) acceleration
D) force
E) Momentum is a scalar and does not have a direction.

A) 7.1 m
B) 21 m
C) 40 m
D) 49 m
E) 64 m

A) particles of the system must be exerting forces on each other
B) the system must be under the influence of gravity
C) the center of mass must have constant velocity
D) a net external force must be acting on the system
E) none of the above

A) zero
B) 0.5 N∙s away from wall
C) 0.5 N∙s toward wall
D) 3.5 N∙s away from wall
E) 3.5 N∙s toward wall

A) kg/m
B) gram.s
C) N.s
D) kg/(m.s)
E) N/s

A) $\Delta$ p_x > 0, $\Delta$ p_y > 0
B) $\Delta$ p_x < 0, $\Delta$ p_y > 0
C) $\Delta$ p_x = 0, $\Delta$ p_y > 0
D) $\Delta$ p_x = 0, $\Delta$ p_y < 0
E) $\Delta$ p_x > 0, $\Delta$ p_y < 0

A) 7.1 m/s²
B) 14 m/s²
C) 20 m/s²
D) 49 m/s²
E) 65 m/s²

A) 3.0 m/s left
B) 3.0 m/s, right
C) 6.0 m/s, right
D) 6.0 m/s, left
E) 17 m/s, right

A) 8.0 m/s
B) 14 m/s
C) 20 m/s
D) 27 m/s
E) 34 m/s

A) equals the negative integral (with respect to distance) of the potential energy function
B) is the ability to do work
C) is the rate of change of doing work
D) equals the time rate of change of momentum
E) has dimensions of momentum multiplied by time

A) Since the explosion exerts external forces on the shell, neither its horizontal momentum nor its vertical momentum is conserved.
B) Since the explosion exerts only internal forces on the shell, both its horizontal and vertical momenta are conserved.
C) Since the explosion exerts only internal forces on the shell, but gravity is an external force, neither its horizontal momentum nor its vertical momentum is conserved.
D) Since the explosion exerts only internal forces on the shell, but gravity is an external force, its horizontal momentum is conserved but its vertical momentum is not conserved.
E) Since the explosion exerts only internal forces on the shell, but gravity is an external force, its vertical momentum is conserved but its horizontal momentum is not conserved.

A) 1.2 kg∙m/s
B) 1.9 kg∙m/s
C) 4.6 kg∙m/s
D) 4.8 kg∙m/s
E) 6.2 kg∙m/s

A) acquires a speed of 1 m/s
B) moves 10 cm
C) acquires a momentum of 1.0 kg . m/s
D) acquires a kinetic energy of 0.1 J
E) none of the above

A) depends on all the forces on all the particles
B) depends on all the velocities of all the particles
C) depends only on the forces external to the system of particles
D) depends only on the forces internal to the system of particles
E) depends only on the force of gravity

A) + 25 N∙s
B) - 25 N∙s
C) + 50 N∙s
D) - 50 N∙s
E) + 100 N∙s

A) depends on how fast the ball was thrown
B) is in the direction of the ball's change in velocity
C) is in the direction of the force of gravity
D) depends on how hard the ball is struck
E) Impulse is a scalar, and does not have a direction associated with it.

A) 0 m/s
B) 2.0 m/s
C) 3.0 m/s
D) 5.0 m/s
E) 7.0 m/s

A) causes a much smaller change in momentum
B) exerts a much smaller impulse
C) causes a much smaller change in kinetic energy
D) exerts a much smaller force
E) does much more work

A) 32 N
B) 64 N
C) 320 N
D) 640 N
E) impossible to determine from given data

A) 0 N∙s
B) 2 N∙s
C) 4 N∙s
D) 8 N∙s
E) cannot be determined without knowing the mass of the object

A) mvT
B) mv/T
C) (1/2)mv²T
D) mv²/(2T)
E) mT²/(2v)

A) cannot be determined without knowing the masses of the particles.
B) is 5.5 N
C) is 3.1 N
D) is 1.9 N
E) cannot be determined without knowing the momentum at t = 0

A) remain at rest
B) move in a circle
C) move in a straight line
D) move in a parabola
E) move along some other curve

A) twice the magnitude of the impulse of Y on X
B) half the magnitude of the impulse of Y on X
C) one-fourth the magnitude of the impulse of Y on X
D) four times the magnitude of the impulse of Y on X
E) the same as the magnitude of the impulse of Y on X

A) 2mnv
B) 2mnv sin 30 $\degree$
C) mnv sin 30 $\degree$
D) mnv cos 30 $\degree$
E) mnv

A) 0.8 m/s
B) 1.3 m/s
C) 1.6 m/s
D) 2.3 m/s
E) 4.0 m/s

A) force
B) power
C) energy
D) momentum
E) work

A) 3.0 N∙s
B) 6.0 N∙s
C) 9.0 N∙s
D) 15 N∙s
E) 29 N∙s

A) cannot be answered without knowing how long it took the box to stop
B) 22 kg∙m/s
C) 120 kg∙m/s
D) 270 kg∙m/s
E) 540 kg∙m/s

A) greater speed than the other body
B) greater acceleration than the other body
C) smaller momentum than the other body
D) greater momentum than the other body
E) the same momentum as the other body

A) 0.6 m/s
B) 1.2 m/s
C) 1.8 m/s
D) 2.4 m/s
E) 3.6 m/s

A) a moving object strikes a stationary object, after which the objects move in arbitrary directions.
B) the objects must be moving along the same line before the collision, but may be moving in arbitrary directions after the collision.
C) one of the objects must remain at rest after the collision.
D) one of the objects must be at rest before the collision.
E) all motion, both before and after the collision, must be along the same line.

A) momentum is not conserved but kinetic energy is conserved
B) total mass is not conserved but momentum is conserved
C) neither kinetic energy nor momentum is conserved
D) momentum is conserved but kinetic energy is not conserved
E) the total impulse is equal to the change in kinetic energy

A) 1.8 m/s
B) 3.2 m/s
C) 5.0 m/s
D) 6.8 m/s
E) 7.1 m/s

A) 0 m/s
B) 2.8 m/s
C) 4.0 m/s
D) 5.2 m/s
E) 8.0 m/s

A) 0 J
B) 1250 J
C) 3750 J
D) 5000 J
E) 5600 J

A) momentum was not conserved, therefore the report must be false
B) if some other form of energy were changed to kinetic during the collision, the report could be true
C) if the collision were elastic, the report could be true
D) if the surface were inclined, the report could be true
E) kinetic energy increased, therefore the report must be false

A) momentum is not conserved but kinetic energy is conserved
B) total mass is not conserved but momentum is conserved
C) kinetic energy and momentum are both conserved
D) momentum is conserved but kinetic energy is not conserved
E) the total impulse is equal to the change in kinetic energy

A) 0 m/s
B) 1.0 m/s
C) 2.3 m/s
D) 2.5 m/s
E) 5.0 m/s

A) 0 m/s
B) 0.38 m/s
C) 0.43 m/s
D) 0.50 m/s
E) 1.0 m/s

A) 0 N∙s
B) 4 N∙s
C) 6 N∙s
D) 9 N∙s
E) 12 N∙s

A) -mv
B) -Mv/m
C) -mv/M
D) -v
E) mv/M

A) 1.0 m/s
B) 1.5 m/s
C) 2.0 m/s
D) 2.3 m/s
E) 3.0 m/s

A) 1.1 m/s forward
B) 1.1 m/s backward
C) 0.0017 m/s forward
D) 0.0017 m/s backward
E) none of these

A) the total kinetic energy before the collision
B) the difference in the kinetic energies of the objects before the collision
C) 1/2Mv²_com, where M is the total mass and v_com is the velocity of the center of mass
D) the kinetic energy of the more massive body before the collision
E) the kinetic energy of the less massive body before the collision

A) unknown since the heat generated in the collision was not given
B) 8.0 * 10² m/s
C) 24.0 m/s
D) 8.0 m/s
E) 2.4 *10⁴ m/s

A) 0 m/s
B) 2.1 * 10^-2 m/s
C) 8.3 * 10^-2 m/s
D) 15 m/s
E) 1.1 m/s

A) the two objects cannot stick together
B) the collision must be elastic
C) the first object must stop
D) momentum is not necessarily conserved
E) none of the above

A) 2:3
B) 3:2
C) 2:1
D) 3:1
E) 6:1

A) 1.33 m/s
B) 0.40 m/s
C) 12.0 m/s
D) 12.6 m/s
E) 40.0 m/s