Gravitation

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A spherical shell has inner radius R1, outer radius R2, and mass M, distributed uniformly throughout the shell. The magnitude of the gravitational force exerted on the shell by a point mass particle of m, located a distance d from the center, inside the inner radius, is: A. 0 B. GMm/R12 C. GM m/d2 D. GMm/(R2−d2) E. GMm/(R1−d)2

A

An artificial satellite of Earth nears the end of its life due to air resistance. While still in orbit: A. it moves faster as the orbit lowers B. it moves slower as the orbit lowers C. it spirals slowly 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

An object at the surface of Earth (at a distance R from the center of Earth) weighs 90N. Its weight at a distance 3R from the center of Earth is: A. 10N B. 30N C. 90N D. 270N E. 810N

A

An object is dropped from an altitude of one Earth radius above Earth's surface. If M is the massof Earth and R is its radius the speed of the object just before it hits Earth is given by: A. GM/R B. GM/2R C. 2GM/R D. √GM/R2 E. √GM/2R2

A

The orbit of a certain satellite has a semimajor axis of 1.5 × 107 m and an eccentricity of 0.20. Its perigee (minimum distance) and apogee (maximum distance) are respectively: 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 ans: A

A

The speed of a comet in an elliptical orbit about the Sun: 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

A planet is in circular orbit around the Sun. Its distance from the Sun is four times the average distance of Earth from the Sun. The period of this planet, in Earth years, is: A. 4 B. 8 C. 16 D. 64 E. 2.52

B

A projectile is fired straight upward from Earth's surface with a speed that is half the escape speed. If R is the radius of Earth, the highest altitude reached, measured from the surface, is: A. R/4 B. R/3 C. R/2 D. R E. 2R

B

Four particles, each with mass m are arranged symmetrically about the origin on the x axis. A fifth particle, with mass M, is on the y axis. The direction of the gravitational force on M is: A. B. C. D. E. ↑ ↓ ← → none of these directions

B

Given the perihelion distance, aphelion distance, and speed at perihelion of a planet, which of the following CANNOT be calculated? 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

B

Let M denote the mass of Earth and let R denote its radius. The ratio g/G at Earth's surface A. R2/M B. M/R2 C. MR2 D. M/R E. R/M

B

Neglecting air resistance, the escape speed from a certain planet for an empty space vehicle is 1.12 × 104 m/s. What is the corresponding escape speed for the fully loaded vehicle, which has triple the mass of the empty one? 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

B

The magnitude of the acceleration of a planet in orbit around the Sun is proportional to: 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

B

Three particles, two with mass m and one with mass M, might be arranged in any of the four configurations known below. Rank the configurations according to the magnitude of the gravitational force on M, least to greatest. 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

B

A planet in another solar system orbits a star with a mass of 4.0 × 1030 kg. At one point in its orbit it is 250 × 106 km from the star and is moving at 35 km/s. Take the universal gravitational constant to be 6.67 × 10−11 m2/s2 · kg and calculate the semimajor axis of the planet's orbit. The result is: A. 79×106km B. 160×106km C. 290×106km D. 320×106km E. 590×106km

C

A spherical shell has inner radius R1, outer radius R2, and mass M, distributed uniformly throughout the shell. The magnitude of the gravitational force exerted on the shell by a point mass m, located a distance d from the center, outside the outer radius, is: A. 0 B. GMm/R12 C. GM m/d2 D. GMm/(R2−d2) E. GMm/(R1−d)2

C

A spring scale, calibrated in newtons, is used to weigh sugar. If it were possible to weigh sugar at the following locations, where will the buyer get the most sugar to a newton? A. At the north pole B. At the equator C. At the center of Earth D. On the Moon E. On Jupiter

C

An astronaut finishes some work on the outside of his satellite, which is in circular orbit around Earth. He leaves his wrench outside the satellite. The wrench will: A. fall directly to 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 Earth

C

An astronaut on the Moon simultaneously drops a feather and a hammer. The fact that they land together shows that: A. no gravity forces act on a body in a vacuum B. the acceleration due to gravity on the Moon is less than on 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 ontheMoon

C

An object is raised from the surface of Earth to a height of two Earth radii above Earth. Then: 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

C

Each of the four corners of a square with edge a is occupied by a point mass m. There is a fifth mass, also m, at the center of the square. To remove the mass from the center to a point far away the work that must be done by an external agent is given by: A. 4Gm2 /a B. −4Gm2 /a C. 4√2Gm2/a D. −4√2Gm2 /a E. 4Gm2 /a2

C

Earth exerts a gravitational force on the Moon, keeping it in its orbit. The reaction to this force, in the sense of Newton's third law, is: A. the centripetal force on the Moon B. the nearly circular orbit of the Moon C. the gravitational force on Earth by the Moon D. the tides due to the Moon E. the apple hitting Newton on the head.

C

For a planet in orbit around a star the perihelion distance is rp ad its speed at perihelion is vp. The aphelion distance is ra and its speed at aphelion is va. Which of the following is true? A. va=vp B. va/ra = vp/rp C. vara=vprp D. va/ra2 = vp/rp2 E. vara2=vprp2

C

If Earth were to rotate only 100 times per year about its axis: 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

C

In planetary motion the line from the star to the planet sweeps out equal areas in equal times. This is a direct consequence of: 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

C

Let F1 be the magnitude of the gravitational force exerted on the Sun by Earth and F2 be the magnitude of the force exerted on Earth by the Sun. Then: 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

C

The escape speed at the surface of Earth is approximately 8 km/s. What is the mass, in units of Earth's mass, of a planet with twice the radius of Earth for which the escape speed is twice that for Earth? A. 2 B. 4 C. 8 D. 1/2 E. 1/4

C

The mass of a hypothetical planet is 1/100 that of Earth and its radius is 1/4 that of Earth. A. 24 N B. 48 N C. 96 N D. 192 N E. 600 N

C

The mass of an object: A. is slightly different at different locations on 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

C

A particle might be placed 1. inside a uniform spherical shell of mass M, but not at the center 2. inside a uniform spherical shell of mass M, at the center 3. outside a uniform spherical shell of mass M, a distance r from the center 4. outside a uniform solid sphere of mass M, a distance 2r from the center Rank these situations according to the magnitude of the gravitational force on the particle, least to greatest. A. All tie B. 1,2,3,4 C. 1and2tie,then3and4tie D. 1and2tie,then3,then4 E. 1and2tie,then4,then3

D

A planet travels in an elliptical orbit about a star X as shown. The magnitude of the acceleration of the planet is: 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

D

A planet travels in an elliptical orbit about a star as shown. At what pair of points is the speed of the planet the same? A. W, S B. P, T C. P, R D. Q, U E. V, R

D

A spaceship is returning to Earth with its engine turned off. Consider only the gravitational field of Earth and let M be the mass of Earth, m be the mass of the spaceship, and R be the distance from the center of Earth. In moving from position 1 to position 2 the kinetic energy of the spaceship increases by: A. GMm 1 − 1 GMm/R2 R2 R12 B. GMm 1 + 1 R12 R2 C. GMmR1−R2 R12 D. GMmR1−R2 R1 R2 E. GMmR1−R2 R 12 R 2 2

D

A spherical shell has inner radius R1 , outer radius R2 , and mass M , distributed uniformly throughout the shell. The magnitude of the gravitational force exerted on the shell by a point particle of mass m located a distance d from the center, outside the inner radius and inside the outer radius, is: A. 0 B. GM m/d2 C. GMm/(R23−d3) D. GMm(d3 − R13)/d2(R23 − R13) E. GMm/(d3−R13)

D

An astronaut in an orbiting spacecraft feels "weightless" because she: A. is beyond the range of gravity B. is pulled outward by centrifugal force C. has no acceleration D. has the same acceleration as the spacecraft E. is outside Earth's atmosphere

D

Assume that Earth is in circular orbit around the Sun with kinetic energy K and potential energy U, taken to be zero for infinite separation. Then, the relationship between K and U: A. isK=U B. isK=−U C. isK=U/2 D. isK=−U/2 E. depends on the radius of the orbit

D

Consider the statement: "Earth moves in a stable orbit around the Sun and is therefore in equilibrium". The statement is: A. false, because no moving body can be in equilibrium B. true, because Earth does not fall into or fly away from the Sun C. false, because Earth is rotating on its axis and no rotating body can be in equilibrium D. false, because Earth has a considerable acceleration E. true, because if it were not in equilibrium then buildings and structures would not be stable

D

Of the following where would the weight of the object be the lowest. 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

D

Planet 1 and planet 2 are both in circular orbits around the same central star. The orbit of planet 2 has a radius that is much larger than the radius of the orbit of planet 1. This means that: 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

D

The gravitational constant G has the derived units: A. N·m B. N·m/kg C. N·kg/m D. N·m2 /kg2 E. N·kg2 /m2

D

The mass density of a certain planet has spherical symmetry but varies in such a way that the mass inside every spherical surface with center at the center of the planet is proportional to the radius of the surface. If r is the distance from the center of the planet to a point mass inside the planet, the gravitational force on the mass is: A. not dependent on r B. proportional to r2 C. proportional to r D. proportional to 1/r E. proportional to 1/r2

D

To measure the mass of a planet with the same radius as Earth, an astronaut drops an object from rest (relative to the planet) from an altitude of one radius above the surface. When the object hits its speed is 4 times what it would be if the same experiment were carried out for Earth. In units of Earth masses, the mass of the planet is: A. 2 B. 4 C. 8 D. 16 E. 32

D

Two particles, each of mass m, are a distance d apart. To bring a third particle, with mass 2m, from far away to a resting point midway between the two particles the work done by an external agent is given by: A. 4Gm2 /d B. −4Gm2 /d C. 8Gm2 /d2 D. −8Gm2 /d2 E. zero

D

Venus has a mass of about 0.0558 times the mass of Earth and a diameter of about 0.381 times the diameter of Earth. The acceleration of a body falling near the surface of Venus is about: A. 0.21 m/s2 B. 1.4 m/s2 C. 2.8 m/s2 D. 3.8 m/s2 E. 25 m/s2

D

In the formula F = Gm1m2/r2, the quantity G: A. depends on the local value of g B. is used only when Earth is one of the two masses C. is greatest at the surface of Earth D. is a universal constant of nature E. is related to the Sun in the same way that g is related to Earth

D.

A rocket ship is coasting toward a planet. Its captain wishes to know the value of g at the surface of the planet. This may be inferred by: 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.

E

A small satellite is in elliptical orbit around Earth as shown. If L denotes the magnitude of its angular momentum and K denotes kinetic energy: A. L2 >L1 andK2 >K1 B. L2 >L1 andK2 =K1 C. L2 =L1 andK2 =K1 D. L2 <L1 andK2 =K1 E. L2 =L1 andK2 >K1

E

An artificial Earth satellite is moved from a circular orbit with radius R to a circular orbit with radius 2R. During this move: 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 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

E

An artificial satellite of Earth releases a bomb. Neglecting air resistance, the bomb will: 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 strike Earth

E

Neglecting air resistance, a 1.0-kg projectile has an escape velocity of about 11km/s at the surface of Earth. The corresponding escape velocity for a 2.0kg projectile is: A. 3.5 km/s B. 5.5 km/s C. 7.1 km/s D. 10 km/s E. 11 km/s

E

Suitable units for the gravitational constant G are: A. kg·m/s2 B. m/s2 C. N·s/m D. kg·m/s E. m3 /(kg·s2 )

E

Suppose you have a pendulum clock that keeps correct time on Earth (acceleration due to gravity = 9.8 m/s2). Without changing the clock, you take it to the Moon (acceleration due to gravity = 1.6 m/s2). For every hour interval (on Earth) the Moon clock will record: A. B. C. D. E. (9.8/1.6) h 1h 9.8/1.6 h (1.6/9.8) h

E

The approximate value of g at an altitude above Earth equal to one Earth diameter is: 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

E

The elliptical orbit of a planet around the Sun is shown on the diagram. Which of the following statements is true? A. the eccentricity of the orbit is less than 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

E

Two planets are orbiting a star in a distant galaxy. The first has a semimajor axis of 150 × 106 km, an eccentricity of 0.20, and a period of 1.0 Earth years. The second has a semimajor axis of 250 × 106 km, an eccentricity of 0.30, and a period of: A. 0.46 Earth years B. 0.57 Earth years C. 1.4 Earth years D. 1.8 Earth years E. 2.2 Earth years

E


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