Deck 8: Conservation of Energy

A) 0 J.
B) 39 J.
C) 78 J.
D) 44 J.

A) 7.0 m/s.
B) 6.8 m/s.
C) 6.6 m/s.
D) 6.4 m/s.

A) 0 J.
B) 13 J.
C) 4.5 J.
D) 9.8 J.

A) 78 J.
B) 13 J.
C) 66 J.
D) 23 J.

A) 3.6 cm.
B) 7.5 cm.
C) 13 cm.
D) 11 cm.

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

A) $\alpha d ^ { 5 } / 5 + \beta d ^ { 3 } / 3$
B) $\alpha d ^ { 4 } + \beta d ^ { 2 }$
C) $2 d \left( 2 \alpha d ^ { 2 } + \beta \right)$
D) $4 \alpha d ^ { 4 } + 3 \beta d ^ { 3 }$

A) 450 J.
B) 220 J.
C) 45 J.
D) 15 J.

A) 1.7 m/s.
B) 1.2 m/s.
C) 2.2 m/s.
D) 2.6 m/s.

A) $L _ { s } - k _ { b } d / \left( k _ { b } + k _ { s } \right)$
B) $L _ { s } - k _ { b } L _ { b } / \left( k _ { b } + k _ { s } \right)$
C) $L _ { b } - k _ { s } L _ { s } / \left( k _ { b } + k _ { s } \right)$
D) $L _ { s } - k _ { s } d / \left( k _ { b } + k _ { s } \right)$

A) 7.7 m/s.
B) 6.5 m/s.
C) 8.2 m/s.
D) 6.9 m/s.

A) 32 rad/s.
B) 26 rad/s.
C) 19 rad/s.
D) 12 rad/s.

A) 6.9 m/s $2$
B) 6.3 m/s $2$
C) 4.5 m/s $2$
D) 5.4 m/s $2$

A) 20 N.
B) 5.7 N.
C) 7.9 N.
D) 0.0 N.

A) $m _ { a }$
B) $m _ { b }$
C) Both masses have the same speed.
D) This cannot be determined unless both masses ( $m _ { a } , m _ { b }$ ) are known.

A) $m _ { a }$
B) $m _ { b }$
C) Both masses have the same acceleration.
D) This cannot be determined unless both masses ( $m _ { a } , m _ { b }$ ) are known.

A) $m _ { a }$
B) $m _ { b }$
C) Both masses reach the bottom at the same time.
D) This cannot be determined unless both the masses ( $m _ { a } , m _ { b }$ ) are known.

A) ball A.
B) ball B.
C) Both have the same.
D) This cannot be determined unless $\mu$ of the rough incline is known.

A) ball A.
B) ball B.
C) Both have the same.
D) This cannot be determined unless $\mu$ of the rough incline is known.

A) ball A.
B) ball B.
C) Both have the same.
D) This cannot be determined unless $\mu$ of the rough incline is known.

A) ball A.
B) ball B.
C) Both reach the bottom at the same time.
D) This cannot be determined unless $\mu$ of the rough incline is known.

A) $f d$
B) $\sqrt { 2 f d / m }$
C) $\frac { 1 } { 2 } m v ^ { 2 }$
D) $m g h$

A) $f d$
B) $\sqrt { 2 f d / m }$
C) $0$
D) $m g h$

A) $\mathrm { fh } / \mathrm { m }$
B) $\sqrt { 2 f h / m }$
C) $0$
D) $m g h$

A) may do net work on a body that moves no net distance during the application of the force.
B) may change the speed of a body that moves no net distance during the application of the force.
C) may do net work on a body undergoing motion confined to a direction perpendicular to the direction of the force.
D) may change the direction of motion of a body that moves no net distance during the application of the force.

A) the line integral of F around a closed path is zero.
B) the line integral of F between points A and B by way of point C is independent of point C.
C) the line integral of F with limits A and B is independent of the order of the limits.
D) there exists an associated potential energy function.

A) gravitational.
B) kinetic.
C) normal.
D) none of the above.

A) kilowatt-hours.
B) kilocalories.
C) kilograms.
D) electron-volts.

A) [force] x [speed].
B) [work] x [acceleration].
C) [energy] / [time].
D) none of the above.

A) BTUs/foot.
B) kilograms-meters/second².
C) watt-feet.
D) horsepower/(feet/second).

A) the radius of the path.
B) the angle the surface of contact makes with horizontal.
C) the height above the bottom point of the sphere.
D) none of the above.

A) the gravitational potential energy of the small body.
B) the speed of the body.
C) the velocity of the body.
D) none of the above.

A) greater than the distance for the frictionless case.
B) equal to the distance for the frictionless case.
C) less than the distance for the frictionless case.
D) unknown; insufficient information is given to determine the answer.

A) U $\propto$ F · dr.
B) U $\propto$ 11ef2d7c_8600_0f4c_a6da_1197495b9a7b_TBN1003_11 F_r dt.
C) U $\propto$ dF_r/dr.
D) U $\propto$ dF_r/dt.

A) F_Y $\propto$ U dy.
B) F_Y $\propto$ 11ef2d7c_8600_0f4c_a6da_1197495b9a7b_TBN1003_11U dt.
C) F_Y $\propto$ dU/dy.
D) F_Y $\propto$ dU/dt.

A) kz².
B) k + a constant.
C) -kz + a constant.
D) kz³.

A) 0.5.
B) 1.0.
C) 2.0.
D) 4.0.

A) 10.0.
B) 22.5.
C) 45.0.
D) 67.5.

A) increases as that reference length increases beyond the unstretched length.
B) increases as that reference length increases beyond any length.
C) remains unchanged as that reference length increases beyond the unstretched length.
D) remains unchanged as that reference length increases beyond any length.

A) the force required to stretch a spring increases as the length of stretching increases.
B) the force required to stretch a spring increases as the absolute length of the spring increases.
C) the force required to stretch a spring remains unchanged as the length of stretching increases.
D) the force required to stretch a spring remains unchanged as the absolute length of the spring increases.

A) the total energy and the kinetic energy.
B) the kinetic energy and the gravitational potential energy.
C) the gravitational potential energy and the spring potential energy.
D) none of the above.

A) the total energy and the gravitational potential energy.
B) the kinetic energy and the spring potential energy.
C) the spring potential energy and the total energy.
D) none of the above.

A) hold just as before.
B) hold, with modification by including thermal energy changes.
C) no longer hold, no matter how modified.
D) Hold it! Nonconservative forces cannot (by definition) be included in the analysis of a system.

A) total energy and kinetic energy.
B) kinetic energy and gravitational potential energy.
C) gravitational potential energy and spring potential energy.
D) none of the above.

A) total energy and gravitational potential energy.
B) kinetic energy and spring potential energy.
C) spring potential energy and total energy.
D) none of the above.

A) F $\times$ v.
B) F · v.
C) F/v.
D) v/F.

A) P = dW/dt.
B) W = dP/dt.
C) Either of the first two responses is valid, depending on the circumstances.
D) Neither of the first two responses is valid.

A) 3.6 x 10⁶ kilowatt-hours = 1 joule.
B) 3.6 x 10⁶ joules = 1 kilowatt-hour.
C) 1/3600 kilowatt-hours = 1 joule.
D) 1/3600 joules = 1 kilowatt-hour.

A) energy must travel at the speed of light.
B) any mass has energy.
C) any energy has mass.
D) none of the above.