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C hapter 9
GRAVITATION
Let us try to understand the motion of the
We have learnt about the motion of objects and moon by recalling activity 7.11.
force as the cause of motion. We have learnt
that a force is needed to change the speed or Activity ______________ 9.1
the direction of motion of an object. We always
observe that an object dropped from a height Take a piece of thread.
Tie a small stone at one end. Hold the
falls towards the earth. We know that all the
other end of the thread and whirl it
planets go around the Sun. The moon goes round, as shown in Fig. 9.1.
around the earth. In all these cases, there must Note the motion of the stone.
be some force acting on the objects, the planets Release the thread.
and on the moon. Isaac Newton could grasp Again, note the direction of motion of
that the same force is responsible for all these. the stone.
This force is called the gravitational force.
In this chapter we shall learn about
gravitation and the universal law of
gravitation. We shall discuss the motion of
objects under the influence of gravitational
force on the earth. We shall study how the
weight of a body varies from place to place.
We shall also discuss the conditions for
objects to float in liquids.

9.1 Gravitation
We know that the moon goes around the earth.
An object when thrown upwards, reaches a
certain height and then falls downwards. It is
said that when Newton was sitting under a tree, Fig. 9.1: A stone describing a circular path with a
an apple fell on him. The fall of the apple made velocity of constant magnitude.
Newton start thinking. He thought that: if the
earth can attract an apple, can it not attract Before the thread is released, the stone
the moon? Is the force the same in both cases? moves in a circular path with a certain speed
He conjectured that the same type of force is and changes direction at every point.
responsible in both the cases. He argued that The change in direction involves change in
at each point of its orbit, the moon falls velocity or acceleration. The force that causes
towards the earth, instead of going off in a this acceleration and keeps the body moving
straight line. So, it must be attracted by the along the circular path is acting towards
earth. But we do not really see the moon falling the centre. This force is called the
towards the earth. centripetal (meaning ‘centre-seeking’) force.

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In the absence of this force, the stone flies off 9.1.1 UNIVERSAL LAW OF GRAVITATION
along a straight line. This straight line will be
a tangent to the circular path. Every object in the universe attracts every
other object with a force which is proportional
to the product of their masses and inversely
Tangent to a circle
proportional to the square of the distance
between them. The force is along the line
joining the centres of two objects.
More to know

A straight line that meets the circle at
one and only one point is called a Mm
F =G 2
tangent to the circle. Straight line d
ABC is a tangent to the circle at
point B.
Fig. 9.2: The gravitational force between two
uniform objects is directed along the line
The motion of the moon around the earth joining their centres.
is due to the centripetal force. The centripetal
force is provided by the force of attraction of Let two objects A and B of masses M and
the earth. If there were no such force, the m lie at a distance d from each other as shown
moon would pursue a uniform straight line in Fig. 9.2. Let the force of attraction between
motion. two objects be F. According to the universal
It is seen that a falling apple is attracted law of gravitation, the force between two
towards the earth. Does the apple attract the objects is directly proportional to the product
earth? If so, we do not see the earth moving of their masses. That is,
towards an apple. Why? F∝M × m (9.1)
According to the third law of motion, the And the force between two objects is inversely
apple does attract the earth. But according proportional to the square of the distance
to the second law of motion, for a given force, between them, that is,
acceleration is inversely proportional to the
mass of an object [Eq. (8.4)]. The mass of an 1
apple is negligibly small compared to that of F∝ (9.2)
d2
the earth. So, we do not see the earth moving
towards the apple. Extend the same argument Combining Eqs. (10.1) and (10.2), we get
for why the earth does not move towards the
moon. M ×m
In our solar system, all the planets go F ∝ d2
(9.3)
around the Sun. By arguing the same way,
we can say that there exists a force between M×m
the Sun and the planets. From the above facts or, F = G 2 (9.4)
d
Newton concluded that not only does the
earth attract an apple and the moon, but all where G is the constant of proportionality and
objects in the universe attract each other. This is called the universal gravitation constant.
force of attraction between objects is called By multiplying crosswise, Eq. (9.4) gives
the gravitational force. F×d2=GM×m

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 2 From Eq. (9.4), the force exerted by the
Fd
or G= (9.5) earth on the moon is
M×m
M ×m
The SI unit of G can be obtained by F =G
d2
substituting the units of force, distance and
mass in Eq. (9.5) as N m2 kg–2. 6.7 × 10 −11 N m 2 kg -2 × 6 × 1024 kg × 7.4 × 1022 kg
=
The value of G was found out by (3.84 × 108 m)2
Henry Cavendish (1731 – 1810) by using a
= 2.02 × 1020 N.
sensitive balance. The accepted value of G is
6.673 × 10–11 N m2 kg–2. Thus, the force exerted by the earth on
We know that there exists a force of the moon is 2.02 × 1020 N.
attraction between any two objects. Compute
the value of this force between you and your

Q
friend sitting closeby. Conclude how you do uestions
not experience this force! 1. State the universal law of
gravitation.
2. Write the formula to find the
The law is universal in the sense that
magnitude of the gravitational
it is applicable to all bodies, whether
force between the earth and an
the bodies are big or small, whether
object on the surface of the earth.
More to know

they are celestial or terrestrial.

Inverse-square 9.1.2 IMPORTANCE OF THE UNIVERSAL
LAW OF GRAVITATION
Saying that F is inversely
proportional to the square of d The universal law of gravitation successfully
means, for example, that if d gets explained several phenomena which were
bigger by a factor of 6, F becomes believed to be unconnected:
1 (i) the force that binds us to the earth;
times smaller. (ii) the motion of the moon around the
36
earth;
(iii) the motion of planets around the Sun;
and
Example 9.1 The mass of the earth is (iv) the tides due to the moon and the Sun.
6 × 1024 kg and that of the moon is
7.4 × 1022 kg. If the distance between the 9.2 Free Fall
earth and the moon is 3.84×105 km,
calculate the force exerted by the earth on Let us try to understand the meaning of free
the moon. (Take G = 6.7 × 10–11 N m2 kg-2) fall by performing this activity.

Solution: Activity 9. 2
The mass of the earth, M = 6 × 1024 kg Take a stone.
The mass of the moon, Throw it upwards.
m = 7.4 × 1022 kg It reaches a certain height and then it
The distance between the earth and the starts falling down.
moon, We have learnt that the earth attracts
d = 3.84 × 105 km objects towards it. This is due to the
= 3.84 × 105 × 1000 m gravitational force. Whenever objects fall
= 3.84 × 108 m towards the earth under this force alone, we
G = 6.7 × 10–11 N m2 kg–2 say that the objects are in free fall. Is there any

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change in the velocity of falling objects? While calculations, we can take g to be more or less
falling, there is no change in the direction of constant on or near the earth. But for objects
motion of the objects. But due to the earth’s far from the earth, the acceleration due to
attraction, there will be a change in the gravitational force of earth is given by
magnitude of the velocity. Any change in Eq. (9.7).
velocity involves acceleration. Whenever an
object falls towards the earth, an acceleration 9.2.1 TO CALCULATE THE VALUE OF g
is involved. This acceleration is due to the
earth’s gravitational force. Therefore, this To calculate the value of g, we should put the
acceleration is called the acceleration due to values of G, M and R in Eq. (9.9), namely,
the gravitational force of the earth (or universal gravitational constant, G = 6.7 × 10–11
acceleration due to gravity). It is denoted by N m2 kg-2, mass of the earth, M = 6 × 1024 kg,
g. The unit of g is the same as that of and radius of the earth, R = 6.4 × 106 m.
acceleration, that is, m s–2.
M
We know from the second law of motion g= G 2
that force is the product of mass and R
acceleration. Let the mass of the stone in
6.7 × 10-11 N m 2 kg -2 × 6 × 1024 kg
activity 9.2 be m. We already know that there =
is acceleration involved in falling objects due (6.4 × 106 m)2
to the gravitational force and is denoted by g. = 9.8 m s–2.
Therefore the magnitude of the gravitational
force F will be equal to the product of mass Thus, the value of acceleration due to gravity
and acceleration due to the gravitational of the earth, g = 9.8 m s–2.
force, that is,
F=mg (9.6) 9.2.2 MOTION OF OBJECTS UNDER THE
From Eqs. (9.4) and (9.6) we have INFLUENCE OF GRAVITATIONAL

M ×m FORCE OF THE EARTH
mg =G 2
d Let us do an activity to understand whether
all objects hollow or solid, big or small, will
M fall from a height at the same rate.
or g = G 2 (9.7)
d
where M is the mass of the earth, and d is the Activity 9.3
distance between the object and the earth. Take a sheet of paper and a stone.
Let an object be on or near the surface of Drop them simultaneously from the
the earth. The distance d in Eq. (9.7) will be first floor of a building. Observe
equal to R, the radius of the earth. Thus, for whether both of them reach the
objects on or near the surface of the earth, ground simultaneously.
We see that paper reaches the ground
M ×m
mg = G (9.8) little later than the stone. This happens
2
R because of air resistance. The air offers
resistance due to friction to the motion
M of the falling objects. The resistance
g=G (9.9)
R
2 offered by air to the paper is more than
the resistance offered to the stone. If
The earth is not a perfect sphere. As the we do the experiment in a glass jar
radius of the earth increases from the poles to from which air has been sucked out,
the equator, the value of g becomes greater at the paper and the stone would fall at
the poles than at the equator. For most the same rate.

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 We know that an object experiences u +v
acceleration during free fall. From Eq. (9.9), (ii) average speed =
2
this acceleration experienced by an object is = (0 m s–1+ 5 m s–1)/2
independent of its mass. This means that all = 2.5 m s–1
objects hollow or solid, big or small, should (iii) distance travelled, s = ½ a t2
fall at the same rate. According to a story, = ½ × 10 m s–2 × (0.5 s)2
Galileo dropped different objects from the top = ½ × 10 m s–2 × 0.25 s2
of the Leaning Tower of Pisa in Italy to prove = 1.25 m
the same. Thus,
As g is constant near the earth, all the (i) its speed on striking the ground
equations for the uniformly accelerated = 5 m s–1
motion of objects become valid with (ii) its average speed during the 0.5 s
acceleration a replaced by g. = 2.5 m s–1
The equations are: (iii) height of the ledge from the ground
v = u + at (9.10) = 1.25 m.
1
s = ut + at2 (9.11)
2
v2 = u2 + 2as (9.12) Example 9.3 An object is thrown vertically
upwards and rises to a height of 10 m.
where u and v are the initial and final velocities Calculate (i) the velocity with which the
and s is the distance covered in time, t. object was thrown upwards and (ii) the
In applying these equations, we will take time taken by the object to reach the
acceleration, a to be positive when it is in the highest point.
direction of the velocity, that is, in the
direction of motion. The acceleration, a will Solution:
be taken as negative when it opposes the
motion. Distance travelled, s = 10 m
Final velocity, v = 0 m s–1
Acceleration due to gravity, g = 9.8 m s–2
Example 9.2 A car falls off a ledge and Acceleration of the object, a = –9.8 m s–2
drops to the ground in 0.5 s. Let (upward motion)
g = 10 m s –2 (for simplifying the (i) v 2 = u2 + 2a s
calculations). 0 = u 2 + 2 × (–9.8 m s–2) × 10 m
(i) What is its speed on striking the –u 2 = –2 × 9.8 × 10 m2 s–2
ground?
u = 196 m s-1
(ii) What is its average speed during the
0.5 s? u = 14 m s-1
(iii) How high is the ledge from the (ii) v=u+at
ground? 0 = 14 m s–1 – 9.8 m s–2 × t
t = 1.43 s.
Solution: Thus,
(i) Initial velocity, u = 14 m s–1, and
Time, t = ½ second (ii) Time taken, t = 1.43 s.
Initial velocity, u = 0 m s–1
Acceleration due to gravity, g = 10 m s–2

Q
Acceleration of the car, a = + 10 m s–2 uestions
(downward) 1. What do you mean by free fall?
(i) speed v = at
2. What do you mean by acceleration
v = 10 m s–2 × 0.5 s
due to gravity?
= 5 m s–1

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9.3 Mass attracts the object. In the same way, the weight
of an object on the moon is the force with
We have learnt in the previous chapter that the which the moon attracts that object. The mass
mass of an object is the measure of its inertia. of the moon is less than that of the earth. Due
We have also learnt that greater the mass, the to this the moon exerts lesser force of attraction
greater is the inertia. It remains the same on objects.
whether the object is on the earth, the moon Let the mass of an object be m. Let its
or even in outer space. Thus, the mass of an weight on the moon be Wm. Let the mass of
object is constant and does not change from the moon be Mm and its radius be Rm.
place to place. By applying the universal law of
gravitation, the weight of the object on the
moon will be
9.4 Weight Mm × m
Wm = G (9.16)
We know that the earth attracts every object Rm2
with a certain force and this force depends on Let the weight of the same object on the
the mass (m) of the object and the acceleration earth be We. The mass of the earth is M and its
due to the gravity (g). The weight of an object radius is R.
is the force with which it is attracted towards
the earth. Table 9.1
We know that
F = m × a, (9.13) Celestial Mass (kg) Radius (m)
that is, body
F = m × g. (9.14)
The force of attraction of the earth on an Earth 5.98 × 1024 6.37 ××106
object is known as the weight of the object. It Moon 7.36 ××1022 1.74 ××106
is denoted by W. Substituting the same in Eq.
(9.14), we have
W=m×g (9.15) From Eqs. (9.9) and (9.15) we have,
As the weight of an object is the force with M ×m
We = G (9.17)
which it is attracted towards the earth, the SI R2
unit of weight is the same as that of force, that
Substituting the values from Table 10.1 in
is, newton (N). The weight is a force acting
Eqs. (9.16) and (9.17), we get
vertically downwards; it has both magnitude
and direction. 7.36 × 1022 kg × m
Wm = G
We have learnt that the value of g is
(1.74 × 10 m )
6 2

constant at a given place. Therefore at a given
place, the weight of an object is directly Wm = 2.431 × 1010 G × m (9.18a)
proportional to the mass, say m, of the object,
and We = 1.474 × 10 G × m
11
(9.18b)
that is, W ∝ m. It is due to this reason that at
a given place, we can use the weight of an Dividing Eq. (9.18a) by Eq. (9.18b), we get
object as a measure of its mass. The mass of
Wm 2.431 × 1010
an object remains the same everywhere, that =
is, on the earth and on any planet whereas its We 1.474 × 1011
weight depends on its location because g Wm 1
depends on location. or W = 0.165 ≈ 6 (9.19)
e

9.4.1 W EIGHT OF AN OBJECT ON Weight of the object on the moon
=
1
THE MOON Weight of the object on the earth 6
We have learnt that the weight of an object on Weight of the object on the moon
the earth is the force with which the earth = (1/6) × its weight on the earth.

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 of the net force in a particular direction (thrust)
Example 9.4 Mass of an object is 10 kg.
and the force per unit area (pressure) acting
What is its weight on the earth?
on the object concerned.
Solution: Let us try to understand the meanings of
Mass, m = 10 kg thrust and pressure by considering the
Acceleration due to gravity, g = 9.8 m s–2 following situations:
W=m×g Situation 1: You wish to fix a poster on a
W = 10 kg × 9.8 m s-2 = 98 N bulletin board, as shown in Fig 9.3. To do this
Thus, the weight of the object is 98 N. task you will have to press drawing pins with
your thumb. You apply a force on the surface
area of the head of the pin. This force is directed
Example 9.5 An object weighs 10 N when perpendicular to the surface area of the board.
measured on the surface of the earth. This force acts on a smaller area at the tip of
What would be its weight when the pin.
measured on the surface of the moon?

Solution:
We know,
Weight of object on the moon
= (1/6) × its weight on the earth.
That is,
W 10
Wm = e = N.
6 6
= 1.67 N.
Thus, the weight of object on the
surface of the moon would be 1.67 N.

Q
uestions
1. What are the differences between
the mass of an object and its
weight?
2. Why is the weight of an object on
1 th
the moon its weight on the
6
earth?

9.5 Thrust and Pressure Fig. 9.3: To fix a poster, drawing pins are pressed
with the thumb perpendicular to the board.
Have you ever wondered why a camel can run
in a desert easily? Why an army tank weighing
more than a thousand tonne rests upon a Situation 2: You stand on loose sand. Your
continuous chain? Why a truck or a motorbus feet go deep into the sand. Now, lie down on
has much wider tyres? Why cutting tools have the sand. You will find that your body will not
sharp edges? In order to address these go that deep in the sand. In both cases the
questions and understand the phenomena force exerted on the sand is the weight of your
involved, it helps to introduce the concepts body.

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 You have learnt that weight is the force by the wooden block on the table top if
acting vertically downwards. Here the force is it is made to lie on the table top with its
acting perpendicular to the surface of the sand. sides of dimensions (a) 20 cm × 10 cm
The force acting on an object perpendicular to and (b) 40 cm × 20 cm.
the surface is called thrust.
When you stand on loose sand, the force, Solution:
that is, the weight of your body is acting on
The mass of the wooden block = 5 kg
an area equal to area of your feet. When you
The dimensions
lie down, the same force acts on an area equal
= 40 cm × 20 cm × 10 cm
to the contact area of your whole body, which
Here, the weight of the wooden block
is larger than the area of your feet. Thus, the
effects of forces of the same magnitude on applies a thrust on the table top.
different areas are different. In the above That is,
cases, thrust is the same. But effects are Thrust = F = m × g
different. Therefore the effect of thrust = 5 kg × 9.8 m s–2
depends on the area on which it acts. = 49 N
The effect of thrust on sand is larger while Area of a side = length × breadth
standing than while lying. The thrust on unit = 20 cm × 10 cm
= 200 cm2 = 0.02 m2
area is called pressure. Thus,
From Eq. (9.20),
thrust
Pressure = (9.20) 49 N
area Pressure = 0.02 m 2
Substituting the SI unit of thrust and area in
Eq. (9.20), we get the SI unit of pressure as N/ = 2450 N m-2.
m2 or N m–2. When the block lies on its side of
In honour of scientist Blaise Pascal, the dimensions 40 cm × 20 cm, it exerts
SI unit of pressure is called pascal, denoted the same thrust.
as Pa. Area= length × breadth
Let us consider a numerical example to = 40 cm × 20 cm
understand the effects of thrust acting on = 800 cm2 = 0.08 m2
different areas. From Eq. (9.20),
49 N
Example 9.6 A block of wood is kept on a Pressure =
0.08 m 2
tabletop. The mass of wooden block is 5
kg and its dimensions are 40 cm × 20 = 612.5 N m–2
cm × 10 cm. Find the pressure exerted The pressure exerted by the side 20 cm
× 10 cm is 2450 N m–2 and by the side
40 cm × 20 cm is 612.5 N m–2.

Thus, the same force acting on a smaller
area exerts a larger pressure, and a smaller
pressure on a larger area. This is the reason
why a nail has a pointed tip, knives have sharp
edges and buildings have wide foundations.

9.5.1 PRESSURE IN FLUIDS
All liquids and gases are fluids. A solid exerts
pressure on a surface due to its weight.
Fig. 9.4 Similarly, fluids have weight, and they also

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exert pressure on the base and walls of the water on the bottle is greater than its weight.
container in which they are enclosed. Pressure Therefore it rises up when released.
exerted in any confined mass of fluid is To keep the bottle completely immersed,
transmitted undiminished in all directions. the upward force on the bottle due to water
must be balanced. This can be achieved by
9.5.2 BUOYANCY an externally applied force acting downwards.
This force must at least be equal to the
Have you ever had a swim in a pool and felt difference between the upward force and the
lighter? Have you ever drawn water from a weight of the bottle.
well and felt that the bucket of water is heavier The upward force exerted by the water on
when it is out of the water? Have you ever the bottle is known as upthrust or buoyant
wondered why a ship made of iron and steel force. In fact, all objects experience a force of
does not sink in sea water, but while the same buoyancy when they are immersed in a fluid.
amount of iron and steel in the form of a sheet The magnitude of this buoyant force depends
would sink? These questions can be answered on the density of the fluid.
by taking buoyancy in consideration. Let us
understand the meaning of buoyancy by 9.5.3 W HY OBJECTS FLOAT OR SINK
doing an activity.
WHEN PLACED ON THE SURFACE OF
Activity ______________ 9.4 WATER?
Take an empty plastic bottle. Close Let us do the following activities to arrive at
the mouth of the bottle with an an answer for the above question.
airtight stopper. Put it in a bucket
filled with water. You see that the Activity ______________ 9.5
bottle floats.
Push the bottle into the water. You feel Take a beaker filled with water.
an upward push. Try to push it further Take an iron nail and place it on the
down. You will find it difficult to push surface of the water.
deeper and deeper. This indicates that Observe what happens.
water exerts a force on the bottle in the
upward direction. The upward force The nail sinks. The force due to the
exerted by the water goes on increasing gravitational attraction of the earth on the
as the bottle is pushed deeper till it is iron nail pulls it downwards. There is an
completely immersed. upthrust of water on the nail, which pushes
Now, release the bottle. It bounces it upwards. But the downward force acting
back to the surface.
on the nail is greater than the upthrust of
Does the force due to the gravitational
water on the nail. So it sinks (Fig. 9.5).
attraction of the earth act on this
bottle? If so, why doesn’t the bottle stay
immersed in water after it is released?
How can you immerse the bottle in
water?

The force due to the gravitational
attraction of the earth acts on the bottle in
the downward direction. So the bottle is
pulled downwards. But the water exerts an
upward force on the bottle. Thus, the bottle is
pushed upwards. We have learnt that weight
of an object is the force due to gravitational
attraction of the earth. When the bottle is Fig. 9.5: An iron nail sinks and a cork floats when
immersed, the upward force exerted by the placed on the surface of water.
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 Activity ______________ 9.6
Take a beaker filled with water.
Take a piece of cork and an iron nail of
equal mass.
Place them on the surface of water.
Observe what happens.

The cork floats while the nail sinks. This
happens because of the difference in their
densities. The density of a substance is
defined as the mass per unit volume. The (a)
density of cork is less than the density of
water. This means that the upthrust of water
on the cork is greater than the weight of the
cork. So it floats (Fig. 9.5).
(b)
The density of an iron nail is more than
the density of water. This means that the Fig. 9.6: (a) Observe the elongation of the rubber
string due to the weight of a piece of stone
upthrust of water on the iron nail is less than
suspended from it in air. (b) The elongation
the weight of the nail. So it sinks. decreases as the stone is immersed
Therefore objects of density less than that in water.
of a liquid float on the liquid. The objects of
density greater than that of a liquid sink in Observe what happens to elongation
the liquid. of the string or the reading on the
balance.

Q
uestions You will find that the elongation of the string
1. Why is it difficult to hold a school or the reading of the balance decreases as the
bag having a strap made of a thin stone is gradually lowered in the water. However,
and strong string? no further change is observed once the stone
2. What do you mean by buoyancy? gets fully immersed in the water. What do you
3. Why does an object float or sink infer from the decrease in the extension of the
when placed on the surface of string or the reading of the spring balance?
water? We know that the elongation produced in
the string or the spring balance is due to the
9.6 Archimedes’ Principle weight of the stone. Since the extension
decreases once the stone is lowered in water,
it means that some force acts on the stone in
Activity ______________ 9.7 upward direction. As a result, the net force on
Take a piece of stone and tie it to one the string decreases and hence the elongation
end of a rubber string or a spring also decreases. As discussed earlier, this
balance. upward force exerted by water is known as
Suspend the stone by holding the the force of buoyancy.
balance or the string as shown in
What is the magnitude of the buoyant
Fig. 9.6 (a).
Note the elongation of the string or force experienced by a body? Is it the same
the reading on the spring balance due in all fluids for a given body? Do all bodies
to the weight of the stone. in a given fluid experience the same buoyant
Now, slowly dip the stone in the water force? The answer to these questions is
in a container as shown in contained in Archimedes’ principle, stated as
Fig. 9.6 (b). follows:

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 When a body is immersed fully or partially Archimedes’ principle has many
in a fluid, it experiences an upward force that applications. It is used in designing ships and
is equal to the weight of the fluid displaced submarines. Lactometers, which are used to
by it. determine the purity of a sample of milk and
Now, can you explain why a further hydrometers used for determining density of
decrease in the elongation of the string was liquids, are based on this principle.
not observed in activity 9.7, as the stone was

Q
fully immersed in water? uestions
Archimedes was a Greek scientist. He 1. You find your mass to be 42 kg
discovered the principle, subsequently named on a weighing machine. Is your
after him, after noticing that mass more or less than 42 kg?
the water in a bathtub 2. You have a bag of cotton and an
overflowed when he stepped iron bar, each indicating a mass
into it. He ran through the of 100 kg when measured on a
streets shouting “Eureka!”, weighing machine. In reality,
which means “I have got it”. one is heavier than other. Can
This knowledge helped him to you say which one is heavier
determine the purity of the and why?
Archimedes
gold in the crown made for
the king.
His work in the field of Geometry and
Mechanics made him famous. His
understanding of levers, pulleys, wheels-
and-axle helped the Greek army in its war
with Roman army.

What
you have
learnt
The law of gravitation states that the force of attraction
between any two objects is proportional to the product of
their masses and inversely proportional to the square of
the distance between them. The law applies to objects
anywhere in the universe. Such a law is said to be universal.
Gravitation is a weak force unless large masses are involved.
The force of gravity decreases with altitude. It also varies
on the surface of the earth, decreasing from poles to the
equator.
The weight of a body is the force with which the earth
attracts it.
The weight is equal to the product of mass and acceleration
due to gravity.
The weight may vary from place to place but the mass stays
constant.

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2024-25
 All objects experience a force of buoyancy when they are
immersed in a fluid.
Objects having density less than that of the liquid in which
they are immersed, float on the surface of the liquid. If the
density of the object is more than the density of the liquid in
which it is immersed then it sinks in the liquid.

Exercises
1. How does the force of gravitation between two objects change
when the distance between them is reduced to half ?
2. Gravitational force acts on all objects in proportion to their
masses. Why then, a heavy object does not fall faster than
a light object?
3. What is the magnitude of the gravitational force between the
earth and a 1 kg object on its surface? (Mass of the earth is
6 × 1024 kg and radius of the earth is 6.4 × 106 m.)
4. The earth and the moon are attracted to each other by
gravitational force. Does the earth attract the moon with a
force that is greater or smaller or the same as the force
with which the moon attracts the earth? Why?
5. If the moon attracts the earth, why does the earth not move
towards the moon?
6. What happens to the force between two objects, if
(i) the mass of one object is doubled?
(ii) the distance between the objects is doubled and tripled?
(iii) the masses of both objects are doubled?
7. What is the importance of universal law of gravitation?
8. What is the acceleration of free fall?
9. What do we call the gravitational force between the earth and
an object?
10. Amit buys few grams of gold at the poles as per the instruction
of one of his friends. He hands over the same when he meets
him at the equator. Will the friend agree with the weight of gold
bought? If not, why? [Hint: The value of g is greater at the
poles than at the equator.]
11. Why will a sheet of paper fall slower than one that is crumpled
into a ball?
1
12. Gravitational force on the surface of the moon is only as
6
strong as gravitational force on the earth. What is the weight
in newtons of a 10 kg object on the moon and on the earth?

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 13. A ball is thrown vertically upwards with a velocity of 49 m/s.
Calculate
(i) the maximum height to which it rises,
(ii) the total time it takes to return to the surface of the
earth.
14. A stone is released from the top of a tower of height 19.6 m.
Calculate its final velocity just before touching the ground.
15. A stone is thrown vertically upward with an initial velocity
of 40 m/s. Taking g = 10 m/s2, find the maximum height
reached by the stone. What is the net displacement and the
total distance covered by the stone?
16. Calculate the force of gravitation between the earth and the
Sun, given that the mass of the earth = 6 × 1024 kg and of the
Sun = 2 × 1030 kg. The average distance between the two is
1.5 × 1011 m.
17. A stone is allowed to fall from the top of a tower 100 m high
and at the same time another stone is projected vertically
upwards from the ground with a velocity of 25 m/s. Calculate
when and where the two stones will meet.
18. A ball thrown up vertically returns to the thrower after 6 s.
Find
(a) the velocity with which it was thrown up,
(b) the maximum height it reaches, and
(c) its position after 4 s.
19. In what direction does the buoyant force on an object
immersed in a liquid act?
20. Why does a block of plastic released under water come up
to the surface of water?
21. The volume of 50 g of a substance is 20 cm3. If the density of
water is 1 g cm–3, will the substance float or sink?
22. The volume of a 500 g sealed packet is 350 cm3. Will the
packet float or sink in water if the density of water is 1 g
cm–3? What will be the mass of the water displaced by this
packet?

112 SCIENCE

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