Deck 13: Gravitation

A) its mass increases and its weight remains constant
B) both its mass and weight remain constant
C) its mass remains constant and its weight decreases
D) both its mass and its weight decrease
E) its mass remains constant and its weight increases

A) no gravity forces act on a body in a vacuum
B) the acceleration due to gravity on the Moon is less than g on the Earth
C) in the absence of air resistance all bodies at a given location fall with the same acceleration
D) the feather has a greater weight on the Moon than on Earth
E) G = 0 on the Moon

A) is beyond the range of gravity
B) is pulled outwards by centrifugal force
C) has no acceleration
D) has the same acceleration as the space-craft
E) is outside Earth's atmosphere

A) depends on the local value of g
B) is used only when the Earth is one of the two masses
C) is greatest at the surface of the Earth
D) is a universal constant of nature
E) is related to the Sun in the same way that g is related to the Earth

A) kg.m/s²
B) m/s²
C) N.s/m
D) kg.m/s
E) m³/(kg.s²)

A) $\uparrow$
B) $\downarrow$
C) $\leftarrow$
D) $\rightarrow$
E) none of these directions

A) F₁ is much greater than F₂
B) F₁ is slightly greater than F₂
C) F₁ is equal to F₂
D) F₁ is slightly less than F₂
E) F₁ is much less than F₂

A) airplanes flying west to east would make better time
B) we would fly off Earth's surface
C) our apparent weight would slightly increase
D) Earth's atmosphere would float into outer space
E) our apparent weight would slightly decrease

A) the centripetal force on the Moon
B) the nearly circular orbit of the Moon
C) the gravitational force exerted on Earth by the Moon
D) the tides due to the Moon
E) the apple hitting Newton on the head

A) the mass of the planet
B) the mass of the Sun
C) the distance between the planet and the Sun
D) the reciprocal of the distance between the planet and the Sun
E) the product of the mass of the planet and the mass of the Sun

A) 0.21 m/s²
B) 1.4 m/s²
C) 2.8 m/s²
D) 3.8 m/s²
E) 25 m/s²

A) R²/M
B) M/R²
C) MR²
D) M/R
E) R/M

A) N.m
B) N.m/kg
C) N.kg/m
D) N.m²/kg²
E) N.kg²/m²

A) strike Earth under the satellite at the instant of release
B) strike Earth under the satellite at the instant of impact
C) strike Earth ahead of the satellite at the instant of impact
D) strike Earth behind the satellite at the instant of impact
E) never strikes Earth

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

A) 9.8 m/s²
B) 4.9 m/s²
C) 2.5 m/s²
D) 1.9 m/s²
E) 1.1 m/s²

A) 24 N
B) 48 N
C) 96 N
D) 192 N
E) 600 N

A) fall directly down to the Earth
B) continue in orbit at reduced speed
C) continue in orbit with the satellite
D) fly off tangentially into space
E) spiral down to the Earth

A) is slightly different at different locations on the Earth
B) is a vector
C) is independent of the acceleration due to gravity
D) is the same for all objects of the same size and shape
E) can be measured directly and accurately on a spring scale

A) 3.5 km/s
B) 5.5 km/s
C) 7.1 km/s
D) 10 km/s
E) 11 km/s

A) 4Gm²/d
B) -4Gm²/d
C) 8Gm²/d²
D) -8Gm²/d²
E) zero

A) false, because no moving body can be in equilibrium
B) true, because the Earth does not fall into or fly away from the sun
C) false, because the Earth is rotating on its axis and no rotating body can be in equilibrium
D) false, because the Earth has a considerable acceleration
E) true, because if it were not in equilibrium then buildings and structures would not be stable

A) the eccentricity of the orbit is less thatn zero
B) the eccentricity of the orbit is greater than 1
C) the sun might be at point C
D) the sun might be at point D
E) the sun might be at point B

A) R/4
B) R/3
C) R/2
D) R
E) 2R

A) not dependent on r
B) proportional to r²
C) proportional to r
D) proportional to 1/r
E) proportional to 1/r²

A) 0
B) GMm/d²
C)
D)
E)

A) greatest at point Q
B) greatest at point S
C) greatest at point U
D) greatest at point W
E) the same at all points

A) 2000 miles above Earth's surface
B) At the north pole
C) At the equator
D) At the center of Earth
E) At the south pole

A) 2
B) 4
C) 8
D) 1/2
E) 1/4

A) 0
B)
C) GMm/d²
D)
E) GMm/(R₁ - d)²

A)
B)
C)
D)
E)

A) All tie
B) 1, 2, 3, 4
C) 1 and 2 tie, then 3 and 4 tie
D) 1 and 2 tie, then 3, then 4
E) 1 and 2 tie, then 4, then 3

A) 0
B)
C) GMm/d²
D)
E) GMm/(R₁ - d)²

A) 3.73 * 10³ m/s
B) 1.12* 10⁴ m/s
C) 3.36 * 10⁴ m/s
D) 9.98 * 10⁴ m/s
E) 1.40 * 10¹² m/s

A) (9.8/1.6) h
B) 1 h
C)
D) (1.6/9.8) h
E)

A) the conservation of energy
B) the conservation of momentum
C) the conservation of angular momentum
D) the conservation of mass
E) none of the above

A) measuring the apparent weight of one of the crew
B) measuring the apparent weight of an object of known mass in the ship
C) measuring the diameter of the planet
D) measuring the density of the planet
E) observing the ship's acceleration and correcting for the distance from the center of the planet

A) 4Gm²/a
B) -4Gm²/a
C)
D)
E) 4Gm²/a²

A) At the north pole
B) At the equator
C) At the center of Earth
D) On the Moon
E) On Jupiter

A) W and S
B) P and T
C) P and R
D) Q and U
E) Vand R

A) 79 *10⁶ km
B) 160 * 10⁶ km
C) 240 * 10⁶ km
D) 320 * 10⁶ km
E) 590 * 10⁶ km

A)
B)
C)
D)
E)

A) 0.46 Earth yr
B) 0.57 Earth yr
C) 1.4 Earth yr
D) 1.8 Earth yr
E) 2.2 Earth yr

A) the period of planet 1 is greater than the period of planet 2 and the speed of planet 1 is greater than the speed of planet 2
B) the period of planet 1 is greater than the period of planet 2 and the speed of planet 1 is less than the speed of planet 2
C) the period of planet 1 is less than the period of planet 2 and the speed of planet 1 is less than the speed of planet 2
D) the period of planet 1 is less than the period of planet 2 and the speed of planet 1 is greater than the speed of planet 2
E) the planets have the same speed and the same period

A) 4
B) 8
C) 16
D) 64
E) 2.52

A) the gravitational force does positive work, the kinetic energy of the satellite increases, and the potential energy of the Earth-satellite system increases
B) the gravitational force does positive work, the kinetic energy of the satellite increases, and the potential energy of the Earth-satellite system decreases
C) the gravitational force does positive work, the kinetic energy of the satellite decreases, and the potential energy of the Earth-satellite system increases
D) the gravitational force does negative work, the kinetic energy of the satellite system increases, and the potential energy of the Earth-satellite system decreases
E) the gravitational force does negative work, the kinetic energy of the satellite decreases, and the potential energy of the Earth-satellite system increases

A) it moves faster as the orbit lowers
B) it moves slower as the orbit lowers
C) it slowly spirals away from Earth
D) it moves slower in the same orbit but with a decreasing period
E) it moves faster in the same orbit but with an increasing period

A) the mass of the star
B) the mass of the planet
C) the speed of the planet at aphelion
D) the period of orbit
E) the semimajor axis of the orbit

A) v_a = v_p
B) v_a/ r_a = v_p/r_p
C) v_a r_a = v_p r_p
D) v_a/ r²_a = v_p/r²_p
E) v_a r²_a = v_p/r²_p

A) 2
B) 4
C) 8
D) 16
E) 32

A) 1.2 *10⁷ m, 1.8 *10⁷ m
B) 3.0 * 10⁶ m, 1.2*10⁷ m
C) 9.6 *10⁶ m, 1.0*10⁷ m
D) 1.0 * 10⁷ m, 1.2 *10⁷ m
E) 9.6 * 10⁶ m, 1.8 * 10⁷ m

A) is K = U
B) is K = -U
C) is K = U/2
D) is K = -U/2
E) depends on the radius of the orbit

A) decreases while it is receding from the sun
B) is constant
C) is greatest when farthest from the sun
D) varies sinusoidally with time
E) equals L/(mr), where L is its angular momentum, m is its mass, and r is its distance from the sun

A) L₂ > L₁ and K₂ > K₁
B) L₂ > L₁ and K₂ = K₁
C) L₂ = L₁ and K₂ = K₁
D) L₂ < L₁ and K₂ = K₁
E) L₂ = L₁ and K₂ > K₁