Deck 8: Systems of Particles and Conservation of Linear Momentum

A)1.26 $\times$ 10⁴ kg · m/s at 48º S of E
B)1.26 $\times$ 10⁴ kg · m/s at 48º S of W
C)1.26 $\times$ 10⁴ kg · m/s at 48º N of W
D)1.78 $\times$ 10⁴ kg · m/s at 48º N of W
E)910 kg · m/s at 48º S of E

A)
B)2
C)
D)4
E)

A)1.0 mN.s
B)2.0 mN.s
C)4.0 mN.s
D)10.0 mN.s
E)40.0 mN.s

A) mv²
B)mv²
C) mv²
D)2mv²
E)4mv²

A)force.
B)momentum.
C)acceleration.
D)mass.
E)potential energy.

A)kg · m · s
B)m²/s
C)kg · s/m
D)kg/J
E)kg · m/s

A)38 m/s
B)13 m/s
C)10 m/s
D)40 m/s
E)27 m/s

A)4.3 $\times$ 10³ m/s
B)4.3 m/s
C)4.8 $\times$ 10^-2 m/s
D)9.5 $\times$ 10^-2 m/s
E)0.34 m/s

A)
B)
C)
D)
E)none of the above

A)energy is conserved.
B)one body is at rest.
C)the net external force is zero.
D)internal forces equal external forces.
E)None of these is correct.

A)
B)
C)
D)
E)

A)kinetic energy is conserved.
B)both momentum and kinetic energy are conserved.
C)neither momentum nor kinetic energy is conserved.
D)the relative velocities before and after impact are equal and oppositely directed.
E)momentum is conserved.

A)speed.
B)potential energy.
C)kinetic energy.
D)momentum.
E)speed,potential energy,kinetic energy,and momentum.

A)zero
B)2.0 m/s
C)3.0 m/s
D)4.5 m/s
E)9.0 m/s

A)elastic collisions
B)inelastic collisions
C)explosions
D)collisions between automobiles
E)All of these are correct.

A)momentum is conserved but the total energy is not conserved.
B)neither the kinetic energy nor the momentum is conserved.
C)neither the total energy nor the momentum is necessarily conserved.
D)the mechanical energy is conserved but momentum is not conserved.
E)both kinetic energy and momentum are conserved.

A)M gets 3/5 of the energy.
B)M gets 1/6 of the energy.
C)M gets 1/5 of the energy.
D)M gets 4/5 of the energy.
E)None of these will occur.

A)its kinetic energy is zero.
B)the sum of all the forces acting on it must be zero.
C)its acceleration is greater than zero and is constant.
D)its center of mass remains at rest.
E)the sum of all the forces acting on the body is constant and nonzero.

A)1/(25 $\pi$ )N.s
B)2/(25 $\pi$ )N.s
C)1/(200 $\pi$ )N.s
D)1/(400 $\pi$ )N.s
E)1/(800 $\pi$ )N.s

A)1.1 m
B)3.3 m
C)0.41 m
D)11 m
E)None of these is correct.

A)zero.
B)equal to their original velocities.
C)equal in magnitude but opposite in direction to their original velocities.
D)less in magnitude and in the same direction as their original velocities.
E)less in magnitude and opposite in direction to their original velocities.

A)zero
B)1.3 m/s
C)2.0 m/s
D)3.0 m/s
E)6.0 m/s

A)8.0 cm/s
B)20 cm/s
C)92 cm/s
D)1.2 m/s
E)1.3 m/s

A)zero.
B)equal to their original velocities.
C)equal in magnitude but opposite in direction to their original velocities.
D)less in magnitude and in the same direction as their original velocities.
E)less in magnitude and opposite in direction to their original velocities.

A)9.1 km/h
B)7.2 km/h
C)3.6 km/h
D)1.8 km/h
E)4.2 km/h

A)0.5 kg
B)1 kg
C)2 kg
D)4 kg
E)cannot be determined

A)1.0 m/s
B)20 m/s
C)6.7 m/s
D)1.5 m/s
E)zero

A)(M + m)/m
B)(M + m)/M
C)M/(m + M)
D)m/(m + M)
E)M/(m - M)

A)an elastic collision with a second particle of much smaller mass.
B)an elastic collision with a second particle of much greater mass.
C)an elastic collision with a second particle of equal mass.
D)an inelastic collision with a second particle of any mass.
E)any type of collision in which the coefficient of restitution is zero.

A)zero.
B)equal to their original velocities.
C)equal in magnitude but opposite in direction to their original velocities.
D)less in magnitude and in the same direction as their original velocities.
E)less in magnitude and opposite in direction to their original velocities.

A)5 N
B)40 N
C)80 N
D)100 N
E)200 N

A)3.2 m/s
B)2.9 m/s
C)1.8 m/s
D)8.3 m/s
E)5.4 m/s

A)8.4 m/s
B)10 m/s
C)8.0 m/s
D)4.0 m/s
E)12 m/s

A)One ball at each end goes off with a speed v.
B)One ball on the side opposite the striking balls goes off with a speed of 2v.
C)The five balls move off together with a speed of 2v/5.
D)Two balls on the side opposite the striking balls go off with a speed of v.
E)None of these will occur.

A)1 m/s
B)2 m/s
C)3 m/s
D)4 m/s
E)8 m/s

A)cannot be found because we don't know whether the surface is frictionless.
B)is 0.21 km/s.
C)is 65 m/s.
D)is 9.3 m/s.
E)None of these is correct.

A)4.4 m/s to the right.
B)2.0 m/s to the right.
C)0 m/s
D)-2.0 m/s to the right.
E)10 m/s to the right.

A)m_1
1 + m<sub>1

1</sub> = m<sub>2

2</sub> + m<sub>2

2</sub>
B) ₂ - ₁ > ₁ - ₂
C) ₂ - ₁ = ₁ - ₂
D) ₂ - ₁ < ₁ - ₂
E) m₁( ₁)² + m₂( ₂)² = m₁( ₁)² + m₂( ₂)²

A)v
B)M₁v
C)(M₁ + M₂)v/M₁
D)M₁v/(M₁ + M₂)
E)M₁v/M₂

A)0.99 kg · m/s
B)5.4 kg · m/s
C)2.2 kg · m/s
D)3.2 kg · m/s
E)0.55 kg · m/s

A)80 m/s² toward the tree.
B)zero with respect to the tree.
C)80 m/s² away from the tree.
D)1.8 $\times$ 10²m/s² with respect to the car.
E)37 m/s² away from the tree.

A)28 m/s
B)42 m/s
C)0.28 km/s
D)26 m/s
E)14 m/s

A)15
B)300
C)800
D)4000
E)48,000

A)up and to the left
B)stops moving
C)up and to the right
D)straight up
E)down and to the right

A)1.80 $\times$ 10⁵ N
B)80.0 N
C)1.80 $\times$ 10² N
D)zero
E)2.20 $\times$ 10⁴ N

A)kinetic energy is conserved.
B)linear momentum is conserved in the absence of external forces.
C)both momentum and kinetic energy are conserved.
D)neither momentum nor kinetic energy is conserved.
E)the extent to which momentum and kinetic energy are conserved depends on the coefficient of restitution.

A)30 m/s,37º N of E
B)30 m/s,37º E of N
C)15 m/s,37º N of E
D)15 m/s,37º E of N
E)42 m/s,37º N of E

A)11 m/s
B)16 m/s
C)23 m/s
D)30 m/s
E)0.11 km/s

A)twice as great.
B)half as great.
C)the same.
D)four times as great.
E)one-fourth as great.

A)0.23 km/s
B)0.10 km/s
C)0.15 km/s
D)0.30 km/s
E)0.27 km/s

A)0.99 kN
B)4.8 kN
C)1.5 kN
D)7.4 kN
E)2.5 kN

A)4.5 m/s
B)2.5 m/s
C)3.3 m/s
D)1.8 m/s
E)1.1 m/s

A)1.2 km
B)5.4 m
C)0.57 km
D)0.29 km
E)0.61 km

A)30º N of E
B)37º N of E
C)45º N of E
D)53º N of E
E)67º N of E

A)3.4 $\times$ 10⁶ m/s
B)1.3 $\times$ 10⁶ m/s
C)0.53 $\times$ 10⁶ m/s
D)1.9 $\times$ 10⁶ m/s
E)6.4 $\times$ 10⁶ m/s

A)14 m/s
B)2.0 m/s
C)2.4 m/s
D)0.20 m/s
E)0.24 km/s

A)500 m/s
B)1.50 km/s
C)400 m/s
D)710 m/s
E)123 m/s

A)momentum is not conserved.
B)momentum is conserved,and the kinetic energy after the collision is less than its value before the collision.
C)momentum is conserved,and the kinetic energy after the collision is the same as the kinetic energy before the collision.
D)momentum is not conserved,and the kinetic energy of the system after the collision differs from the kinetic energy of the system before the collision.
E)the kinetic energy of the system after the collision depends on the masses of the objects.

A)2.1 m/s
B)3.0 m/s
C)4.9 m/s
D)7.0 m/s
E)16 m/s

A)
B)
C)
D)
E)(A)and (B)

A)0.51 kgm/s
B)0.59 kgm/s
C)1.2 kgm/s
D)3.3 kgm/s
E)0.82 kgm/s

A)2mv
B)mv
C)zero
D)-mv
E)-2mv

A)(k $\times$ (M+m))^1/2 $\times$ d/M
B)(k $\times$ (M))^1/2 $\times$ d/m
C)(k $\times$ (M+m))^1/2 $\times$ d/m
D)(k $\times$ (M-m))^1/2 $\times$ d/m
E)(k $\times$ (M+m))^1/2 $\times$ d/2m

A)0.12 kN
B)89 N
C)9.2 N
D)0.49 N
E)It cannot be determined without knowing how high the ball bounces.

A)11%
B)36%
C)50%
D)64%
E)89%

A)20 m/s
B)3.5 m/s
C)25 m/s
D)5.0 m/s
E)2.2 m/s

A)1.5 $\times$ 10⁴ N
B)2.3 $\times$ 10³ N
C)9.8 $\times$ 10^-3 N
D)2.0 $\times$ 10² N
E)4.7 $\times$ 10^-2 N

A)27 N
B)190 N
C)47 N
D)60 N
E)94 N

A)0.5v_c
B)0.75v_c
C)0.87v_c
D)v_c
E)1.15v_c

A)ball A
B)ball B
C)They both experience the same impulse.
D)It is impossible to tell without knowing the masses of the balls.
E)It is impossible to tell without knowing the durations of the collisions.

A)m₁ v₁ = m₁v₁' cos $\alpha$ + m₂v₂' cos $\theta$
B)0 = m₁v₁' cos $\alpha$ + m₂v₂' cos $\theta$
C)m₁ v₁ = m₁v₁' sin $\alpha$ + m₂v₂' sin $\theta$
D)0 = m₁v₁' sin $\alpha$ + m₂v₂' sin $\theta$
E)none of the above

A)Momentum is conserved in the x direction.
B)Momentum is conserved in the y direction.
C)The total momentum before equals the total momentum after the collision.
D)The kinetic energies are conserved.
E)All of the above statements are true.

A)79 g
B)24 g
C)28 g
D)15 g
E)123 g

A)It cannot be determined because the mass of the particle is not given.
B)4.8 N
C)10 N
D)5.3 N
E)9.4 N

A)M $\times$ (1gL/3)^1/2/m
B)M $\times$ (2gL/3)^1/2/m
C)M $\times$ (3gL/4)^1/2/m
D)m $\times$ (4gL/3)^1/2/M
E)M $\times$ (4gL/3)^1/2/m

A)-0.35 m/s
B)+0.25 m/s
C)+0.75 m/s
D)+0.35 m/s
E)+0.40 m/s

A) -4.0 $\times$ 10⁵ J
B) -5.3 $\times$ 10⁵ J
C) - 8.0 $\times$ 10⁵ J
D) -1.3 $\times$ 10⁶ J
E) -1.6 $\times$ 10⁶ J

A)m₁V/ 3m₂
B)2m₁V/ 3m₂
C)m₂V/ 3m₁
D)2m₂V/ 3m₁
E)4m₂V/ 9m₁

A)0.86 V
B)1.33 V
C)1.14 V
D)1.25 V
E)1.00 V