CBSE · NCERT · Class 11 Physics · Chapter 7

NCERT Solutions: Class 11 Physics Chapter 7 - Gravitation

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Chapter-wise NCERT intext questions and exercise answers for Gravitation, grounded in the official textbook.

Questions are taken verbatim from the NCERT textbook; answers were grounded against the chapter's content during generation. Items needing review are marked.
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Q.7.1Answer the following : (a) You can shield a charge from electrical forces by putting it inside a hollow conductor. Can you shield a body from the gravitational influence of nearby matter by putting it inside a hollow sphere or by some other means ? (b) An astronaut inside a small space ship orbiting around the earth cannot detect gravity. If the space station orbiting around the earth has a large size, can he hope to detect gravity ? (c) If you compare the gravitational force on the earth due to the sun to that due to the moon, you would find that the Sun’s pull is greater than the moon’s pull. (you can check this yourself using the data available in the succeeding exercises). However, the tidal effect of the moon’s pull is greater than the tidal effect of sun. Why ?v
Solution

Unlike electric fields in conductors, gravity cannot be shielded by surrounding a body with matter. In a small orbiting spaceship, astronaut and ship are in free fall together, so gravity is not locally felt. In a large station, the gravitational field is slightly different at different parts of the station, so tidal effects can reveal it. The sun's total pull on earth is larger, but tidal effect depends on the field gradient, proportional to $M/r^3$, and the moon's much smaller distance makes its tidal effect stronger.

Answer:

(a) No. Gravitational shielding is not possible. (b) Yes, if the station is large enough, small variations of gravity across it may be detected. (c) Tides depend on the difference in gravitational pull across the earth, which varies as $M/r^3$; the moon is much closer, so its tidal effect is larger.

Q.7.2Choose the correct alternative : (a) Acceleration due to gravity increases/decreases with increasing altitude. (b) Acceleration due to gravity increases/decreases with increasing depth (assume the earth to be a sphere of uniform density). (c) Acceleration due to gravity is independent of mass of the earth/mass of the body. (d) The formula –G Mm(1/r2 – 1/r1) is more/less accurate than the formula mg(r2 – r1) for the difference of potential energy between two points r2 and r1 distance away from the centre of the earth.v
Solution

Outside the earth, $g=GM/r^2$, so it decreases with altitude. Inside a uniform earth, $g\propto r$, so it decreases as depth increases. Acceleration due to gravity is independent of the falling body's mass. The exact gravitational potential-energy difference uses the inverse-radius formula; $mg(r_2-r_1)$ is only a near-surface approximation.

Answer:

(a) decreases. (b) decreases. (c) mass of the body. (d) more accurate.

Q.7.3Suppose there existed a planet that went around the Sun twice as fast as the earth. What would be its orbital size as compared to that of the earth ?v
Solution

By Kepler's third law, $T^2\propto R^3$. If the planet goes around twice as fast, its period is $T_E/2$. Hence $R/R_E=(T/T_E)^{2/3}=(1/2)^{2/3}=0.63$.

Answer:

Its orbital radius would be $2^{-2/3}$ times the earth's orbital radius, about $0.63$ times as large.

Q.7.4Io, one of the satellites of Jupiter, has an orbital period of 1.769 days and the radius of the orbit is 4.22 × 108 m. Show that the mass of Jupiter is about one-thousandth that of the sun.v
Solution

For a satellite in circular orbit, $M=4\pi^2r^3/(GT^2)$. Here $T=1.769\times86400=1.528\times10^5\,\text{s}$ and $r=4.22\times10^8\,\text{m}$. Thus $M_J=\frac{4\pi^2(4.22\times10^8)^3}{(6.67\times10^{-11})(1.528\times10^5)^2}=1.90\times10^{27}\,\text{kg}$. Compared with $M_S\approx2.0\times10^{30}\,\text{kg}$, this is $9.5\times10^{-4}M_S$.

Answer:

$M_J\approx1.90\times10^{27}\,\text{kg}$, which is about $9.5\times10^{-4}$ of the sun's mass, i.e. about one-thousandth.

Q.7.5Let us assume that our galaxy consists of 2.5 × 1011 stars each of one solar mass. How long will a star at a distance of 50,000 ly from the galactic centre take to complete one revolution ? Take the diameter of the Milky Way to be 105 ly.v
Solution

Treat the galactic mass as $M=2.5\times10^{11}(2.0\times10^{30})=5.0\times10^{41}\,\text{kg}$. The radius is $r=50000\,\text{ly}=50000(9.46\times10^{15})=4.73\times10^{20}\,\text{m}$. Using $T=2\pi\sqrt{r^3/(GM)}$, $T=1.12\times10^{16}\,\text{s}=3.55\times10^8\,\text{years}$.

Answer:

About $3.5\times10^8$ years.

Q.7.6Choose the correct alternative: (a) If the zero of potential energy is at infinity, the total energy of an orbiting satellite is negative of its kinetic/potential energy. (b) The energy required to launch an orbiting satellite out of earth’s gravitational influence is more/less than the energy required to project a stationary object at the same height (as the satellite) out of earth’s influence.v
Solution

For a circular orbit, $K=GMm/(2r)$ and $U=-GMm/r$, so total energy $E=K+U=-GMm/(2r)=-K=U/2$. An orbiting satellite already has kinetic energy, so the extra energy needed to escape is $GMm/(2r)$, less than the $GMm/r$ needed for a stationary object at the same radius.

Answer:

(a) negative of its kinetic energy. (b) less.

Q.7.7Does the escape speed of a body from the earth depend on (a) the mass of the body, (b) the location from where it is projected, (c) the direction of projection, (d) the height of the location from where the body is launched?v
Solution

Escape speed from distance $r$ is $v_e=\sqrt{2GM/r}$. The body's mass cancels out, and direction does not enter the energy condition. For a spherical earth it depends only on distance from the earth's centre, so height matters, while different locations at the same height have the same ideal escape speed.

Answer:

(a) No. (b) No, for points at the same height in the ideal spherical-earth model. (c) No. (d) Yes; it decreases with height.

Q.7.8A comet orbits the sun in a highly elliptical orbit. Does the comet have a constant (a) linear speed, (b) angular speed, (c) angular momentum, (d) kinetic energy, (e) potential energy, (f) total energy throughout its orbit? Neglect any mass loss of the comet when it comes very close to the Sun.v
Solution

The sun's gravitational force is central, so torque about the sun is zero and angular momentum is conserved. In an elliptical orbit the comet's distance from the sun changes, so speed, angular speed, kinetic energy and potential energy change. Since gravity is conservative and mass loss is neglected, total mechanical energy remains constant.

Answer:

(a) No. (b) No. (c) Yes. (d) No. (e) No. (f) Yes.

Q.7.9Which of the following symptoms is likely to afflict an astronaut in space (a) swollen feet, (b) swollen face, (c) headache, (d) orientational problem.v
Solution

In weightlessness, body fluids are not pulled toward the feet as on earth, so the face may swell and headache can occur. The absence of the usual up-down cue also causes orientational problems. Swollen feet are less likely because fluid does not pool in the feet.

Answer:

(b), (c), and (d): swollen face, headache and orientational problem.

Q.7.10In the following two exercises, choose the correct answer from among the given ones: The gravitational intensity at the centre of a hemispherical shell of uniform mass density has the direction indicated by the arrow (see Fig 7.11) (i) a, (ii) b, (iii) c, (iv) 0.v
  1. i. a
  2. ii. b
  3. iii. c
  4. iv. 0
Solution

At the centre of the hemispherical shell, horizontal components from symmetric mass elements cancel. The remaining gravitational intensity is along the axis toward the shell material, which is arrow c in Fig. 7.11.

Answer:

(iii) c.

Q.7.12A rocket is fired from the earth towards the sun. At what distance from the earth’s centre is the gravitational force on the rocket zero ? Mass of the sun = 2×1030 kg, mass of the earth = 6×1024 kg. Neglect the effect of other planets etc. (orbital radius = 1.5 × 1011 m).v
Solution

Let the point be at distance $x$ from earth's centre. If the earth-sun distance is $R$, set gravitational pulls equal: $\frac{GM_E}{x^2}=\frac{GM_S}{(R-x)^2}$. Thus $x=\frac{R}{1+\sqrt{M_S/M_E}}$. With $R=1.5\times10^{11}\,\text{m}$, $M_S=2\times10^{30}\,\text{kg}$ and $M_E=6\times10^{24}\,\text{kg}$, $x=2.59\times10^8\,\text{m}$.

Answer:

$2.6\times10^8\,\text{m}$ from the earth's centre towards the sun.

Q.7.13How will you ‘weigh the sun’, that is estimate its mass? The mean orbital radius of the earth around the sun is 1.5 × 108 km.v
Solution

For earth's nearly circular orbit, $GM_S/r^2=4\pi^2r/T^2$, so $M_S=4\pi^2r^3/(GT^2)$. With $r=1.5\times10^8\,\text{km}=1.5\times10^{11}\,\text{m}$ and $T=1\,\text{year}=3.156\times10^7\,\text{s}$, the mass comes out close to $2.0\times10^{30}\,\text{kg}$.

Answer:

Use earth's orbital radius and period: $M_S=4\pi^2r^3/(GT^2)\approx2.0\times10^{30}\,\text{kg}$.

Q.7.14A saturn year is 29.5 times the earth year. How far is the saturn from the sun if the earth is 1.50 × 108 km away from the sun ?v
Solution

By Kepler's third law, $(T_S/T_E)^2=(R_S/R_E)^3$. Thus $R_S=R_E(29.5)^{2/3}=1.50\times10^8(29.5)^{2/3}=1.43\times10^9\,\text{km}$.

Answer:

$1.43\times10^9\,\text{km}$.

Q.7.15A body weighs 63 N on the surface of the earth. What is the gravitational force on it due to the earth at a height equal to half the radius of the earth ?v
Solution

At height $h=R/2$, distance from earth's centre is $r=3R/2$. Gravitational force varies as $1/r^2$, so $F=63\left(\frac{R}{3R/2}\right)^2=63\times\frac{4}{9}=28\,\text{N}$.

Answer:

$28\,\text{N}$.

Q.7.16Assuming the earth to be a sphere of uniform mass density, how much would a body weigh half way down to the centre of the earth if it weighed 250 N on the surface ?v
Solution

Inside a uniform spherical earth, $g$ is proportional to distance $r$ from the centre. Halfway down to the centre means $r=R/2$, so the weight is half the surface weight: $250/2=125\,\text{N}$.

Answer:

$125\,\text{N}$.

Q.7.17A rocket is fired vertically with a speed of 5 km s-1 from the earth’s surface. How far from the earth does the rocket go before returning to the earth ? Mass of the earth = 6.0 × 1024 kg; mean radius of the earth = 6.4 × 106 m; G = 6.67 × 10–11 N m2 kg–2.v
Solution

Use conservation of energy per unit mass. At launch, $E=\frac12v^2-GM/R$. At the highest point, speed is zero and $E=-GM/r_{max}$. Hence $\frac{1}{r_{max}}=\frac{1}{R}-\frac{v^2}{2GM}$. With $v=5000\,\text{m s}^{-1}$, $R=6.4\times10^6\,\text{m}$ and $GM=6.67\times10^{-11}\times6.0\times10^{24}$, $r_{max}=8.0\times10^6\,\text{m}$ from earth's centre. The height is $r_{max}-R=1.6\times10^6\,\text{m}$.

Answer:

It rises to about $1.6\times10^6\,\text{m}$ above the earth's surface.

Q.7.18The escape speed of a projectile on the earth’s surface is 11.2 km s–1. A body is projected out with thrice this speed. What is the speed of the body far away from the earth? Ignore the presence of the sun and other planets.v
Solution

At infinity, $\frac12mv_{\infty}^2=\frac12m(v^2-v_e^2)$. With $v=3v_e$, $v_{\infty}=\sqrt{9v_e^2-v_e^2}=\sqrt8\,v_e=2.828(11.2)=31.7\,\text{km s}^{-1}$.

Answer:

$31.7\,\text{km s}^{-1}$.

Q.7.19A satellite orbits the earth at a height of 400 km above the surface. How much energy must be expended to rocket the satellite out of the earth’s gravitational influence? Mass of the satellite = 200 kg; mass of the earth = 6.0×1024 kg; radius of the earth = 6.4 × 106 m; G = 6.67 × 10–11 N m2 kg–2.v
Solution

The orbital radius is $r=6.4\times10^6+4.0\times10^5=6.8\times10^6\,\text{m}$. A circular satellite has total energy $E=-GMm/(2r)$. To escape with zero speed at infinity, the required energy is $GMm/(2r)=\frac{(6.67\times10^{-11})(6.0\times10^{24})(200)}{2(6.8\times10^6)}=5.9\times10^9\,\text{J}$.

Answer:

$5.9\times10^9\,\text{J}$.

Q.7.20Two stars each of one solar mass (= 2×1030 kg) are approaching each other for a head on collision. When they are a distance 109 km, their speeds are negligible. What is the speed with which they collide ? The radius of each star is 104 km. Assume the stars to remain undistorted until they collide. (Use the known value of G).v
Solution

Initial separation is $r_i=10^9\,\text{km}=10^{12}\,\text{m}$. They touch when centre separation is $r_f=2(10^4\,\text{km})=2\times10^7\,\text{m}$. By energy conservation, total kinetic energy at collision is $Mv^2$ for two equal masses each moving with speed $v$. Thus $Mv^2=GM^2(1/r_f-1/r_i)$, so $v=\sqrt{GM(1/r_f-1/r_i)}=2.6\times10^6\,\text{m s}^{-1}$.

Answer:

Each star collides with speed about $2.6\times10^6\,\text{m s}^{-1}$; their relative speed is about $5.2\times10^6\,\text{m s}^{-1}$.

Q.7.21Two heavy spheres each of mass 100 kg and radius 0.10 m are placed 1.0 m apart on a horizontal table. What is the gravitational force and potential at the mid point of the line joining the centres of the spheres ? Is an object placed at that point in equilibrium? If so, is the equilibrium stable or unstable ?v
Solution

The midpoint is $0.5\,\text{m}$ from each sphere's centre. The gravitational fields due to the two equal spheres are equal and opposite, so net force is zero. Potential adds algebraically: $V=-\frac{GM}{0.5}-\frac{GM}{0.5}=-\frac{2G(100)}{0.5}=-2.67\times10^{-8}\,\text{J kg}^{-1}$. A small displacement along the line makes the nearer sphere pull more strongly, so the object moves farther away from the midpoint; the equilibrium is unstable.

Answer:

The net gravitational force is zero. The gravitational potential is $-2.67\times10^{-8}\,\text{J kg}^{-1}$. An object there is in unstable equilibrium.