Exploring Forces Class 8 NCERT Free Notes and Mind Map (Free PDF Download)

Forces are all around us in our daily lives, from pushing a door open to riding a bicycle against the wind. When we cycle up a hill or feel the pull of gravity as we come down a slope, we are experiencing different types of forces at work.

What Is a Force?

Force is basically a push or pull that we apply on objects around us. Whenever we want to move something, change how fast it’s going, change its direction, or even change its shape, we need to apply a force.

Think about moving a heavy cardboard box – you can push it, pull it, or even lift it up. In all these cases, you are applying force on the box. Without applying any push or pull, the box would just stay where it is. This shows us that force is needed to make things happen.

The push or pull applied on an object is called force in science. Force always involves at least two objects – one that applies the force and another that receives it. When you push a table with your hand, your hand is applying force on the table.

What Can a Force Do to the Bodies on Which It Is Applied?

Forces can do many different things to objects, and we see these effects in our daily lives all the time. Let’s study what forces can achieve when they act on different objects.

Effects of Forces

Making Objects Move from Rest

When you kick a football that is lying still on the ground, your foot applies force and the ball starts moving
A car starts moving when the engine applies force through the wheels
You can make a book slide across a table by pushing it with your hand

Changing Speed of Moving Objects

When you apply brakes on a bicycle, you slow it down by applying force
A cricket bat hits a moving ball and makes it go faster in a different direction
Pressing the accelerator in a car makes it go faster by applying more force

Changing Direction of Motion

A hockey stick hits a moving ball and changes its direction
When you turn the steering wheel of a car, you change the direction the car is moving
A tennis racket hits a ball coming towards you and sends it back in the opposite direction

Changing Shape of Objects

When you press an inflated balloon, it changes shape
Stretching a rubber band changes its shape from short to long
Rolling chapati dough with a rolling pin flattens it and changes its shape

Force as Interaction

It’s imp to understand that forces result from interaction between two or more objects. When you push a table, both your hand and the table are involved in this interaction. Your hand applies force on the table, and interestingly, the table also applies an equal force back on your hand (though you might not always notice this).

Are Forces an Interaction Between Two or More Objects?

Yes, forces always involve interaction between objects. There cannot be a force without at least two objects being involved. One object applies the force, and another object receives it.

When you think about all the examples of forces around you, you’ll notice that there are always two objects interacting. A person pushing a car involves the person and the car. A magnet attracting iron involves the magnet and the iron piece. Even when you walk, your foot interacts with the ground to create the force that moves you forward.

The SI unit of force is newton, written with a small ‘n’, and its symbol is N. This unit is named after the scientist Isaac Newton who made many imp discoveries about forces and motion.

What Are the Different Types of Forces?

Forces can be classified into two main categories based on whether the objects need to touch each other or not.

Contact Forces

Contact forces are those forces where physical contact is necessary between the objects. The contact can be direct (like using your hands) or indirect (like using a stick or rope).

Muscular Force

Muscular force is the force that comes from the action of muscles in our body. Whenever we walk, run, lift something, push something, jump, or stretch, we are using muscular force.

How Muscular Force Works

Muscles contract (get shorter) and elongate (get longer) to create force
When you bend your arm, some muscles contract while others elongate
This coordinated action of muscles creates the force needed for movement

Examples of Muscular Force in Daily Life

Walking and running require muscular force from leg muscles
Lifting your school bag uses muscular force from arm and back muscles
Even simple actions like writing use small muscular forces in your fingers

Muscular Force in Animals

Animals, birds, fish, and insects all use muscular forces for movement and survival
Birds use muscular force to flap their wings and fly
Fish use muscular force to swim through water
Even tiny insects use muscular force to crawl and jump

Human Use of Animal Muscular Force

For thousands of years, humans have used the muscular force of animals for various tasks
Horses, oxen, and buffaloes have been used to pull carts and plough fields
Elephants have been used to lift heavy logs and move large objects
Even today, in many parts of the world, animals help humans with heavy work

Internal Body Functions

Muscular force is not just used for external movements. It plays an imp role in many functions inside our body too:

Digestion: Muscles in our digestive system push food through the alimentary canal
Circulation: The heart muscle contracts and expands to pump blood throughout our body
Breathing: Muscles in our chest help us breathe in and out
Chewing: Jaw muscles help us chew food and break it down

Friction

Friction is another type of contact force that we encounter everywhere in our daily lives. Have you noticed that when you roll a ball on the ground, it eventually stops on its own? Or when you stop pedaling your bicycle on a flat road, it slows down and comes to a stop? This happens because of friction.

What is Friction

Friction is the force that comes into play when an object moves or tries to move over another surface
It always acts in a direction opposite to the direction in which the object is moving or trying to move
Friction is a contact force because it arises due to two surfaces being in contact

Why Friction Occurs

Friction occurs due to irregularities in the surfaces that are in contact
Even surfaces that appear very smooth to our eyes have many tiny bumps and valleys
When two surfaces are placed in contact, these irregularities lock into each other
This locking opposes any effort to move one surface over the other

Factors Affecting Friction

Nature of surfaces: Rough surfaces create more friction than smooth surfaces
Force pressing surfaces together: More pressure between surfaces increases friction
Area of contact: Though this might seem obvious, the area of contact has less effect than you might think

Types of Surfaces and Friction

Different surfaces create different amounts of friction:

Surface Type	Friction Level	Examples
Very smooth	Low friction	Ice, polished marble
Moderately smooth	Medium friction	Wood, ceramic tiles
Rough	High friction	Sandpaper, rough concrete
Very rough	Very high friction	Sand, gravel

Friction in Different Media

Friction doesn’t just occur on solid surfaces. It also acts when objects move through liquids and gases:

Air resistance: When planes, cars, or trains move through air, they experience friction
Water resistance: Ships, boats, and swimmers experience friction when moving through water
Design considerations: Vehicles are designed with special shapes to reduce friction and move more efficiently

Non-contact Forces

Non-contact forces are those forces whose effects can be experienced even when objects are not touching each other. These forces can act across empty space and are quite common in nature.

Magnetic Force

We have learned about magnets and their properties earlier. Magnets can attract objects made of magnetic materials like iron, nickel, and cobalt. They can also attract or repel other magnets.

Properties of Magnetic Force

Like poles (North-North or South-South) repel each other
Unlike poles (North-South) attract each other
Magnetic force can act through non-magnetic materials like paper, plastic, or glass
The strength of magnetic force decreases as the distance between magnets increases

Demonstrating Magnetic Force
When you place two ring magnets with like poles facing each other, you can see one magnet floating above the other. If you try to push the upper magnet down, you can feel the force pushing back against your hand. This shows that magnets can exert force without touching.

Uses of Magnetic Force

Magnetic force is used in many devices like electric motors, generators, and speakers
Magnetic compasses use Earth’s magnetic field to show direction
MRI machines in hospitals use strong magnetic fields to create images of inside our body
Magnetic force is used in maglev trains that float above tracks

Electrostatic Force

Electrostatic force is the force exerted by objects that have electric charges on them. This might sound complicated, but it’s actually quite easy to observe and understand.

Creating Static Charges
When certain materials are rubbed together, they acquire electrical charges on their surfaces. These are called static charges because they don’t move by themselves. The object that gets these charges is called a charged object.

Observing Electrostatic Force

When you rub a plastic scale with a piece of cloth, it becomes charged
If you then bring this charged scale close to small pieces of paper, the paper pieces jump towards the scale
This happens because the charged scale exerts an electrostatic force on the uncharged paper pieces

Properties of Electric Charges
There are two types of electric charges: positive and negative.

Like charges repel: Two objects with the same type of charge push each other away
Unlike charges attract: Objects with different types of charges pull towards each other
Uncharged objects: Charged objects can attract uncharged objects made of certain materials

Examples of Electrostatic Force

When you rub a balloon on your hair and then bring it close to your hair, the hair strands move towards the balloon
Sometimes when you take off a woolen sweater, you hear crackling sounds – this is due to static charges
Lightning is a dramatic example of electrostatic force in nature

Connection to Electric Current

When static charges start moving, they create electric current in electrical circuits. This is the same current that makes bulbs glow, creates heating effects in appliances, and produces magnetic effects in electromagnets.

Gravitational Force

Gravitational force is probably the most familiar force to us, even though we might not always think about it. This is the force that keeps us on the ground and makes things fall when we drop them.

What is Gravitational Force

Gravitational force is the force with which the Earth attracts objects towards itself
This force is also called force of gravity or simply gravity
It is always an attractive force – it always pulls objects towards the Earth’s center

Characteristics of Gravitational Force

Gravitational force acts on all objects, regardless of their size, shape, or material
It acts without any contact between the Earth and the object
The force always acts vertically downward towards the center of the Earth
Gravitational force is always attractive, unlike magnetic or electrostatic forces which can be repulsive too

Vertical Motion Under Gravity

When objects move under the influence of gravitational force, they follow predictable patterns:

Dropping Objects

When you drop an object from a height, it falls straight down
The object starts from rest and speeds up as it falls
All objects fall at the same rate in the absence of air resistance

Throwing Objects Upward

When you throw an object straight up, it first moves up while slowing down
At the highest point, it stops for a moment
Then it starts falling back down, speeding up as it comes down
The path is always straight and vertical

Why Objects Slow Down Going Up
When you throw something upward, gravitational force acts downward (opposite to the motion), causing the object to slow down until it stops. Then the same gravitational force makes it fall back down, causing it to speed up.

Weight and Its Measurement

Weight is a concept that is closely related to gravitational force, and it’s imp to understand the difference between weight and mass.

What is Weight?

Weight is the force with which the Earth pulls an object towards itself. When we say something is heavy, we’re really talking about how strongly the Earth attracts it.

Important Points about Weight

Weight is a force, so it is measured in newtons (N)
Weight depends on gravitational force, which can vary slightly from place to place
The same object will have different weights on different planets
Weight is always directed towards the center of the Earth

Difference Between Weight and Mass

This is a very imp concept that many people find confusing:

Aspect	Mass	Weight
Definition	Amount of matter in an object	Gravitational force on an object
Unit	Kilogram (kg) or gram (g)	Newton (N)
Variation	Remains same everywhere	Changes with gravitational field
Measurement tool	Beam balance	Spring balance
Nature	Scalar quantity	Vector quantity (has direction)

Mass

Mass is the amount of matter in an object
It remains the same whether you are on Earth, Moon, or anywhere else
Mass is measured using a beam balance by comparing with known masses

Weight

Weight is the gravitational force acting on an object
It changes when gravitational force changes (like on different planets)
Weight is measured using a spring balance

Weight on Different Planets

Here’s how the weight of a 1 kg object would vary on different celestial bodies:

Location	Mass	Weight
Earth	1 kg	10 N
Moon	1 kg	1.6 N
Mars	1 kg	3.8 N
Venus	1 kg	9 N
Jupiter	1 kg	25.4 N

This table shows that while mass remains constant, weight changes dramatically based on the gravitational pull of each celestial body.

Measuring Weight with Spring Balance

A spring balance is a device used to measure weight (force). It works on a simple principle:

How Spring Balance Works

When you hang an object from the hook, the spring stretches
The amount of stretching is proportional to the weight of the object
A scale on the balance shows the weight in newtons
Usually, there’s also a scale showing mass in grams (calculated assuming Earth’s gravity)

Using Spring Balance Properly

Never exceed the maximum weight limit of the balance
Read the scale carefully at eye level to avoid errors
Make sure the balance is hanging freely and not touching anything
Check that the pointer reads zero when nothing is hanging from it

Everyday Use of Weight and Mass

In daily life, we often use the terms weight and mass interchangeably, which can be confusing:

When we say “the weight of this bag is 5 kg,” we’re actually talking about its mass
Scientifically, we should say “the mass of this bag is 5 kg” or “the weight of this bag is 50 N”
For practical purposes on Earth, this confusion doesn’t matter much
But in scientific work, it’s imp to use the correct terms with correct units

Floating and Sinking

When we place objects in water, some float while others sink to the bottom. This happens because of the interaction between gravitational force and another force called buoyant force.

Understanding Buoyant Force

When you try to push an empty plastic bottle into water, you can feel it pushing back against your hand. This upward push that you feel is called buoyant force or upthrust.

What is Buoyant Force

Buoyant force is the upward force applied by a liquid on objects placed in it
All liquids apply this upward force on objects immersed in them
The force is always directed upward, opposite to the direction of gravitational force

Why Do Some Objects Float and Others Sink?

Whether an object floats or sinks depends on the balance between two forces:

Forces Acting on Objects in Liquids

Gravitational force: Acts downward, trying to pull the object down
Buoyant force: Acts upward, trying to push the object up

Conditions for Floating and Sinking

If gravitational force > buoyant force → Object sinks
If gravitational force = buoyant force → Object floats
If gravitational force < buoyant force → Object rises to surface

Factors Affecting Buoyant Force

The buoyant force depends on several factors:

Volume of liquid displaced: Larger objects displace more liquid and experience greater buoyant force
Density of the liquid: Denser liquids provide greater buoyant force
Depth of immersion: How much of the object is underwater affects the buoyant force

Archimedes’ Principle

Archimedes, a famous Greek scientist, discovered an imp principle about buoyant force:

Archimedes’ Principle States
When an object is fully or partially immersed in a liquid, it experiences an upward force equal to the weight of the liquid it displaces.

Applications of Archimedes’ Principle

If weight of displaced liquid < weight of object → Object sinks
If weight of displaced liquid = weight of object → Object floats
If weight of displaced liquid > weight of object → Object rises until equilibrium

Practical Examples

Why Ships Float

Large ships are made of steel, which is denser than water
However, ships have hollow spaces filled with air
The overall density of the ship (including air spaces) is less than water
Therefore, ships float even though they’re made of materials denser than water

Why Some Rocks Float

Pumice rock is formed during volcanic eruptions
When lava with lots of gas and water vapor cools quickly, it traps tiny air bubbles
These air pockets make pumice less dense than water
Therefore, pumice rocks can float on water despite being made of rock material

Floating and Sinking

Objects behave differently when placed in liquids – some float on the surface while others sink to the bottom. This interesting phenomenon can be explained by understanding the forces acting on objects in liquids.

Forces Acting on Objects in Liquids

When any object is placed in a liquid, two main forces act on it:

Gravitational Force (Downward)

The Earth pulls the object downward with gravitational force
This force tries to make the object sink
The strength of this force depends on the mass of the object

Buoyant Force (Upward)

The liquid pushes the object upward with buoyant force
This force tries to make the object float
The strength of this force depends on how much liquid the object pushes away

Understanding Buoyant Force Better

What Creates Buoyant Force

When an object is placed in liquid, it pushes some liquid out of the way
The liquid pushes back with an upward force
This upward push from the liquid is called buoyant force or upthrust

Observing Buoyant Force

When you try to push an empty bottle underwater, you feel resistance
The bottle seems to want to pop back up to the surface
This upward push you feel is the buoyant force of water

Conditions for Floating and Sinking

The behavior of objects in liquids depends on which force is stronger:

Condition	Result	Example
Weight > Buoyant force	Object sinks	Stone in water
Weight = Buoyant force	Object floats	Wood piece in water
Weight < Buoyant force	Object rises up	Air-filled balloon underwater

Real-Life Applications

Ship Design

Ships are made of steel, which is much denser than water
However, ships have large hollow areas filled with air
These air spaces reduce the overall density of the ship
The ship displaces a large volume of water, creating enough buoyant force to keep it afloat

Life Jackets

Life jackets are filled with materials that trap air
This makes the overall density of a person wearing a life jacket less than water
Therefore, the person floats even if they cannot swim

Hot Air Balloons

Hot air balloons work on the same principle
Hot air inside the balloon is less dense than cool air outside
This creates enough buoyant force to lift the balloon and basket

Questions and Answers

What is the difference between push and pull forces?

Push force is when you apply force away from your body to move an object in the direction opposite to yourself, like pushing a door to open it or pushing a cart forward from behind
Pull force is when you apply force towards your body to move an object in your direction, like pulling a rope to draw water from a well or pulling a drawer to open it
Both push and pull are types of forces that can produce the same effects like changing motion, speed, direction, or shape of objects
The main difference is the direction in which force is applied relative to the person applying it, but both can achieve similar results in moving objects
Examples of push forces include pressing a button, pushing a swing, or kicking a ball, while examples of pull forces include opening a door towards yourself, pulling a suitcase, or drawing a bow string

Why do we feel lighter when we are in water?

When we enter water, our body displaces some water and pushes it out of the way, creating space for our body in the water
According to Archimedes’ principle, water pushes back on our body with an upward force called buoyant force that is equal to the weight of water displaced
This upward buoyant force acts opposite to the downward gravitational force (our weight), partially canceling out the effect of gravity on our body
The net downward force we experience becomes less than our actual weight, making us feel lighter and more able to move easily in water
This is why people can float in water and why it’s easier to lift someone who has fallen into a swimming pool compared to lifting them on land
The same principle explains why heavy ships can float on water despite being made of materials much denser than water

How is friction both helpful and harmful?

Friction is helpful because it allows us to walk without slipping, helps car brakes stop vehicles safely, enables us to write with pencils on paper, and helps us grip objects without them sliding out of our hands
Friction is also essential for many sports activities like running, where athletes need grip between their shoes and the track, or in cricket where bowlers need friction to spin the ball
However, friction can be harmful because it causes wear and tear in machine parts, reduces efficiency of engines by converting useful energy into heat, causes vehicle tires to wear out, and creates resistance that makes vehicles consume more fuel
In machines, friction leads to energy loss as heat, requiring regular maintenance and lubrication to reduce its negative effects, and can cause moving parts to get damaged over time
Engineers try to reduce harmful friction using lubricants like oil and grease while maintaining beneficial friction where it’s needed for safety and functionality

Why do all objects fall towards Earth and not towards each other?

All objects do actually attract each other with gravitational force, but the Earth is so much more massive than everyday objects that its gravitational pull is overwhelmingly stronger
Earth’s mass is approximately 6 × 10²⁴ kilograms, which is billions of times more massive than any object we encounter in daily life, making its gravitational effect dominant
The gravitational force between two objects depends on both their masses – the more massive the objects, the stronger the attraction between them
While a book and a table do attract each other gravitationally, this force is so incredibly small compared to Earth’s pull that we cannot observe or feel it
Earth’s gravitational field extends far beyond its surface, affecting all objects within this field and pulling them towards Earth’s center, which is why everything falls downward
Only objects with very large masses like planets, stars, and moons have gravitational effects that we can easily observe, such as how the Moon’s gravity causes ocean tides on Earth

What happens to weight and mass when you go to the Moon?

Your mass remains exactly the same on the Moon as it is on Earth because mass is the amount of matter in your body, and this doesn’t change based on location
However, your weight becomes much less on the Moon because weight is the gravitational force acting on your mass, and Moon’s gravity is only about 1/6th as strong as Earth’s gravity
If you weigh 60 kg (actually 600 N) on Earth, you would still have a mass of 60 kg on the Moon, but your weight would be only about 100 N (equivalent to 10 kg on Earth’s surface)
This means you could jump much higher and farther on the Moon, carry heavier objects easily, and move around with much less effort than on Earth
Astronauts on the Moon could perform feats that would be impossible on Earth, like jumping several meters high or carrying equipment that would be too heavy to lift on Earth
This difference between mass and weight is why scientists are careful to use the correct units – mass in kilograms and weight in newtons

How do different surfaces affect the amount of friction?

Smooth surfaces like polished marble, ice, or glass create very little friction, making it easy for objects to slide but difficult to stop or change direction quickly
Rough surfaces like sandpaper, concrete, or gravel create much more friction, making it harder to start sliding but easier to stop and control movement
The amount of friction depends on the microscopic bumps and valleys on surfaces – even apparently smooth surfaces have tiny irregularities that create friction
Different materials have different coefficients of friction, meaning some material combinations naturally create more friction than others regardless of surface smoothness
Wet surfaces generally have less friction than dry surfaces, which is why roads become slippery when it rains and why we need to be more careful when walking on wet floors
Engineers and designers consider friction when choosing materials for different applications – using low-friction materials for bearings and high-friction materials for brake pads and shoe soles

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