Deck 7: Conservation of Energy

A)Susana gains more gravitational potential energy than Sean.
B)Susana gains less gravitational potential energy than Sean.
C)Susana gains the same gravitational potential energy as Sean.
D)To compare energies,we must know the height of the mountain.
E)To compare energies,we must know the lengths of the two trails.

A)must be at the initial position of the object.
B)must be at the final position of the object.
C)must be at ground level.
D)must be at the lowest position ever reached by the object.
E)can be chosen arbitrarily.

A)1.8 $\times$ 10⁷ J
B)1.2 $\times$ 10⁷ J
C)3.8 $\times$ 10⁶ J
D)6.0 $\times$ 10⁷ J
E)1.8 $\times$ 10⁶ J

A)1.2 $\times$ 10⁴ J
B)5.9 $\times$ 10⁴ J
C)4.7 $\times$ 10⁴ J
D)3.8 $\times$ 10⁴ J
E)5.9 $\times$ 10³ J

A)The quarks are tied together by nonstretchable strings.
B)The quarks are tied together by elastic strings.
C)The quarks move independently of each other.
D)The force between the quarks has a 1/r² behavior like gravity.
E)The potential energy of a quark decreases with separation.

A)The work done by a conservative force on an object is independent on the path taken.
B)The work done by a conservative force on an object along path A $\to$ B is negative that of path B $\to$ A.
C)The force due to gravity is an example of a conservative force.
D)Friction is an example of a conservative force.
E)The work done by friction on an object depends on the path taken.

A)20 J
B)more than 20 J
C)less than 20 J
D)It is impossible to tell without knowing the mass of the body.
E)It is impossible to tell without knowing how far the body falls.

A)between A & B and E & F
B)between B & C and C & D
C)between B & C and D & E
D)at points B and D
E)at points C and E

A)1
B)2
C)3
D)4
E)5

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

A)2 J
B)4 J
C)6 J
D)8 J
E)10 J

A)B and D.
B)C and E.
C)B,C,D,and E.
D)A and F.
E)any point between C and D.

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

A)19.6 m/s
B)384 m/s
C)73 m/s
D)43.2 m/s
E)The problem cannot be solved because the shape of the curved slide is not given.

A)always the work done by gravity.
B)the difference between the kinetic and potential energy at any point.
C)the sum of the kinetic and potential energy at any point.
D)the sum of the translational and rotational kinetic energies at any point.
E)the potential energy of a spring at any displacement.

A)2.74 s and 17.4 kJ
B)2.74 s and 468 kJ
C)2.74 s and 468 MJ
D)0.37 s and 468 MJ
E)2.74 s and 17.4 MJ

A)The kinetic and potential energies of an object must always be positive quantities.
B)The kinetic and potential energies of an object must always be negative quantities.
C)Kinetic energy can be negative but potential energy cannot.
D)Potential energy can be negative but kinetic energy cannot.
E)None of these statements is true.

A)1.2 $\times$ 10⁴ J
B)2.4 J
C)2.7 $\times$ 10⁴ J
D)27 J
E)1.2 J

A)Friction is a conservative force and does negative work.
B)Potential energy may be defined by the equation U(x)= -dF(x)/dx
C)The work done by a conservative force between two points depends on the path taken between those points.
D)A conservative force cannot change a body's total energy.
E)The work done by a conservative force while a body moves at constant velocity must be zero.

A)30 kJ
B)0.10 kJ
C)0.29 kJ
D)0.46 kJ
E)0.39 kJ

A)6,.1 m
B)6,.2 m
C)3,.2 m
D)3,.1 m
E)1,2 cm

A)the kinetic energy of the block just before it collides with the spring will be equal to mgh.
B)the kinetic energy of the block when it has fully compressed the spring will be equal to mgh.
C)the potential energy of the block when it has fully compressed the spring will be zero.
D)the energy stored in the spring plus the gravitational potential energy of the block when it has fully compressed the spring will be equal to mgh.
E)None of the above statements will be true.

A)x
B)2x
C)3x
D)4x
E)6x

A)1.1 m/s
B)2.5 m/s
C)3.1 m/s
D)3.4 m/s
E)4.1 m/s

A)27 cm,R
B)3.0 cm,R
C)27 cm,L
D)3.0 cm,L
E)51 cm,R

A)5.1 m
B)30 m
C)97 m
D)10 m
E)The answer depends on the mass of the woman.

A)mg/k
B)mg cos $\theta$ /k
C)mg sin $\theta$ /k
D)mgh sin $\theta$ /(kx)
E)None of the above statements is correct.

A)0.27 J
B)0.71 J
C)0.98 J
D)1.25 J
E)none of the above

A)98.0 J
B)19.6 J
C)3.92 J
D)3.40 J
E)64.0 J

A)3.4 m/s,R
B)3.9 m/s,R
C)3.9 m/s,L
D)2.9 m/s,L
E)2.9 m/s,R

A)the kinetic energy of the block just before it collides with the spring will be equal to mgh.
B)the kinetic energy of the block when it has fully compressed the spring will be equal to mgh.
C)the kinetic energy of the block when it has fully compressed the spring will be zero.
D)the kinetic energy of the block just before it collides with the spring will be kx².
E)None of the above statements will be true.

A)12.5 J
B)34.2 J
C)123 J
D)345 J
E)403 J

A) $\Delta$ U < 0 and $\Delta$ K > 0
B) $\Delta$ U = 0 and $\Delta$ K > 0
C) $\Delta$ U < 0 and $\Delta$ K = 0
D) $\Delta$ U = 0 and $\Delta$ K = 0
E) $\Delta$ U > 0 and $\Delta$ K < 0

A) mgL
B) mgL₁
C) mgL₂
D) mgL₁²/(L)
E) mgL₁L₂/(L)

A)20.0 J
B)169 J
C)266 J
D)438 J
E)94.0 J

A)
B)
C)
D)
E)

A)always positive.
B)always dependent upon the time.
C)always independent of the path.
D)zero.
E)never completely recoverable.

A)11 m/s
B)8.8 m/s
C)14 m/s
D)6.3 m/s
E)12 m/s

A)0.10 kJ
B)0.29 kJ
C)0.36 kJ
D)0.46 kJ
E)0.39 kJ

A)1 J
B)9 J
C)3 $\times$ 10⁸ J
D)3 $\times$ 10¹⁶ J
E)9 $\times$ 10¹⁶ J

A)9.08 $\times$ 10 ^-31 kg
B)8.82 $\times$ 10 ^-14 kg
C)2.94 $\times$ ^-22 kg
D)5.68 $\times$ 10 ^-12 kg
E)None of these is correct.

A)MeV
B)MeV·c²
C)c²/MeV
D)1/MeV
E)MeV/c²

A)5.00 $\times$ 10 ^-19 kg
B)1.50 $\times$ 10 ^-10 kg
C)1.67 $\times$ 10 ^-27 kg
D)1.04 $\times$ 10 ^-8 kg
E)2.34 $\times$ 10 ^-29 kg

A)2.187 $\times$ 10 ^-15 J
B)3.029 $\times$ 10 ^-19 J
C)3.33 $\times$ 10 ^-9 J
D)6.623 $\times$ 10 ^-34 J
E)None of these is correct.

A)MeV
B)MeV·c²
C)c²/MeV
D)1/MeV
E)MeV/c²

A)an object is traveling at a constant velocity.
B)an object has a very small mass.
C)the kinetic energy of an object is much less than its rest mass.
D)an object is not traveling at the speed of light.
E)the kinetic energy of an object is much greater than its rest mass.

A)1.50 $\times$ 10 ^-10 MeV
B)3.13 MeV
C)847 MeV
D)939 MeV
E)742 MeV

A)5.38 $\times$ 10 ^-15
B)1.08 $\times$ 10 ^-11
C)3.23 $\times$ 10 ^-6
D)9.68 $\times$ 10⁵
E)None of these is correct.

A)6.48 $\times$ 10 ^-8
B)1.04 $\times$ 10 ^-7
C)2.33 $\times$ 10 ^-7
D)3.73 $\times$ 10 ^-7
E)None of these is correct.

A)0
B)0.511 MeV
C)1.022 MeV
D)2.044 MeV
E)None of these is correct.

A)deuterons can be broken up by bombarding them with electromagnetic radiation possessing energy of at least 2.22 MeV.
B)deuterons can be broken up by bombarding them with particles possessing energy of at least 2.22 MeV.
C)if the deuterons are bombarded with particles whose energy exeeds 2.22 MeV,the excess energy appears as kinetic energy of the outgoing particles.
D)if the deuterons are bombarded with particles whose energy is less than 2.22 MeV,they will not be decomposed into their constituent parts.
E)all of these are correct.

A)8.20 $\times$ 10 ^-14 MeV
B)0.512 MeV
C)2.73 $\times$ 10 ^-22 J
D)0.00171 MeV
E)0.171 MeV

A)6.17 $\times$ 10¹⁴ Hz
B)2.45 $\times$ 10¹⁸ Hz
C)2.55 $\times$ 10⁸ Hz
D)6.623 $\times$ 10³⁴ Hz
E)None of these is correct.