Deck 3: Energy

A)She continues to spin at the same rate.
B)She spins more rapidly.
C)She spins more slowly.
D)Any of the choices could be correct, depending on how heavy her arms are.

A)attracts light waves passing nearby.
B)repels light waves passing nearby.
C)may attract or repel light waves passing nearby, depending upon the circumstances.
D)has no effect on light waves passing nearby.

A)linear momentum
B)angular momentum
C)kinetic energy
D)potential energy
E)Both A and B

A)depends on the mass.
B)corresponds to a KE equal to its rest energy.
C)is the speed of sound.
D)is the speed of light.

A)0.
B)less than 100 m.
C)100 m.
D)more than 100 m.

A)newton-meter
B)joule
C)kilogram-meter
D)watt-hour

A)horizontal distance the ball is shifted.
B)height the ball is raised.
C)sum of the horizontal distance the ball is shifted and the height the ball is raised.
D)length of the plank.

A)conservation of energy.
B)conservation of linear momentum.
C)conservation of angular momentum.
D)the first law of motion.

A)is the correct formula if v is properly interpreted.
B)always gives too high a value.
C)is the low-speed approximation to the correct formula.
D)is the high-speed approximation of the correct formula.

A)time intervals
B)the speed of an object
C)the speed of sound
D)the speed of light

A)potential energy
B)kinetic energy
C)rest energy
D)momentum
E)Both B, C, and D

A)its KE is halved.
B)its PE is halved.
C)its rest energy is halved.
D)its momentum is halved.

A)energy.
B)work.
C)momentum.
D)power.

A)speed.
B)potential energy.
C)kinetic energy.
D)rest energy.

A)with the speed v while the bowling ball stops.
B)faster than v while the bowling ball continues slower than v.
C)with the speed v while the bowling ball moves backward.
D)together with the bowling ball at the same speed of less than v.

A)speed
B)acceleration
C)kinetic energy
D)potential energy
E)Both A and C

A)acts only on moving bodies.
B)is really a general acceleration of the universe.
C)is a distortion in space-time.
D)is the same as in Newton's theory but is to be interpreted differently.

A)the momentum of each object.
B)the kinetic energy of each object.
C)the total momentum of all the objects.
D)the total kinetic energy of all the objects.

A)kinetic energy.
B)potential energy.
C)mass energy.
D)momentum.

A)0.
B)0.5 mv
C)mv
D)2 mv

A)0.22 kN.
B)0.34 kN.
C)0.45 kN.
D)2.49 kN.

A)9.4 min.
B)46 min.
C)1.5 h.
D)9.2 h.

A)61 J.
B)600 J.
C)2940 J.
D)5880 J.

A)0.45 m/s.
B)1 m/s.
C)1.4 m/s.
D)4.4 m/s.

A)14 m/s.
B)15 m/s.
C)20 m/s.
D)40 m/s.

A)10.2 cm.
B)1 m.
C)9.8 m.
D)98 m.

A)10 m.
B)98 m.
C)960 m.
D)245,000 m.

A)80 kgm/s.
B)2000 kgm/s.
C)5000 kgm/s.
D)19,600 kgm/s.

A)1.2 m/s.
B)3.4 m/s.
C)34 m/s.
D)107 m/s.

A)0.
B)10.2 J.
C)100 J.
D)980 J.

A)25.2 kJ.
B)247 kJ.
C)2.42 MJ.
D)3.2 MJ.

A)1.6 N.
B)2 N.
C)8 N.
D)16 N.

A)1 J.
B)10 J.
C)100 J.
D)1,000 J.

A)3.3 W.
B)33 W.
C)1960 W.
D)117.6 kW.

A)about 5.4 m/s.
B)about 7.7 m/s.
C)about 29.4 m/s.
D)dependent on the child's mass.

A)0.45 m/s.
B)1 m/s.
C)1.4 m/s.
D)4.4 m/s.

A)5 W.
B)14 W.
C)20 W.
D)196 W.

A)0.95 m/s.
B)30 m/s.
C)94 m/s.
D)900 m/s.

A)70 W.
B)335 W.
C)600 W.
D)250,000 W.

A)6.7 * 10^-11 kg.
B)5.4 * 10^-9 kg.
C)6.7 * 10^-3 kg.
D)2.0 * 10^-2 kg.

A)0.2 mm/s.
B)2 mm/s.
C)2 cm/s.
D)20 cm/s.

A)8 km/h.
B)40 km/h.
C)56 km/h.
D)60 km/h.

A)8 km/h.
B)40 km/h.
C)56 km/h.
D)60 km/h.

A)3.7 * 10^-24 J.
B)3.3 * 10^-7 J.
C)100 J.
D)3.0 * 10¹⁰ J.

A)0.
B)less than that lost by the cars in question 48.
C)the same as that lost by the cars in question 48.
D)more than that lost by the cars in question 48.

A)2 W.
B)20 W.
C)200 W.
D)2000 W.