Answer: When the table moves with constant velocity, its acceleration is zero. According to Newton’s first law of motion, if acceleration is zero, the net force acting on the object must be zero. Therefore, the frictional force exerted by the floor on the table is equal in magnitude to the applied force F, but acts in the opposite direction.

Frictional force = F (opposite to the direction of motion).

Answer:

(i) …the velocity of the ball will remain the same. Reason: According to Newton’s first law of motion, an object continues to move with the same velocity unless acted upon by an unbalanced force.

(ii) …the magnitude of the velocity of the ball will increase. Reason: A force in the direction of motion produces acceleration in the same direction, so the speed increases.

(iii) …the magnitude of the velocity of the ball will decrease. Reason: A force opposite to the direction of motion produces retardation, so the speed decreases.

Answer: (i) P experiences a net force and Q does not experience a net force.
For block P: Two opposite forces 5 N and 4 N act on it. Net force on P = 5 N − 4 N = 1 N. So, block P experiences a net force.
For block Q: It is moving with constant velocity on a smooth horizontal surface. Therefore, acceleration is zero and net force on Q is zero.

Answer:
Number of oarsmen rowing in the forward-driving direction = 95
Force applied by each oarsman = 200 N
Total forward force = 95 × 200 = 19000 N
Number of oarsmen rowing in the opposite direction = 5
Total backward force = 5 × 200 = 1000 N
Net force = Forward force − Backward force
Net force = 19000 N − 1000 N = 18000 N
The net force on the snake boat is 18000 N in the forward direction.

Answer: (iv) in the direction of force, with acceleration proportional to the force acting on the object.
According to Newton’s second law of motion: Acceleration is produced in the direction of the net force. Acceleration is directly proportional to the applied force. Acceleration is inversely proportional to the mass of the object.

Answer: (iii) Object C.
In a position-time graph, a straight line means constant velocity, so acceleration is zero and net force is zero. A horizontal line means the object is at rest, so acceleration is zero and net force is zero. A curved line means velocity is changing, so acceleration is present and hence a net force acts. Observing the graphs:
Object A: straight line upward → constant velocity → no net force
Object B: horizontal line → at rest → no net force
Object C: curved line upward → changing velocity → net force acts
Object D: straight line downward → constant negative velocity → no net force.

Answer: Yes, the boat will move.
Direction: The boat will move in the direction opposite to the direction in which the sailor jumps.
When the sailor jumps forward, he pushes the boat backward. According to Newton’s third law of motion, every action has an equal and opposite reaction. The forward force applied by the sailor on the ground (or shore) results in an equal backward force on the boat. Hence, the boat moves backward.

Answer: A landing mat or sand bed is used to reduce the impact force on the athlete.
When the athlete lands, their momentum becomes zero. According to Newton’s second law, force depends on the rate of change of momentum. A soft surface (mat or sand) increases the time taken to stop. Increasing the time of impact reduces the force experienced by the body. The mat or sand bed reduces injury by decreasing the force of impact.

Answer: (iv) the loaded cart and the empty cart both exert an equal magnitude of force on each other.
According to Newton’s third law of motion, every action has an equal and opposite reaction. Hence, both carts exert equal and opposite forces on each other.

Answer: From Newton’s second law: F = ma.
Given graph shows acceleration decreases as mass increases, which means force is constant. Therefore: Force does not change with mass. The force-mass graph will be a straight horizontal line parallel to the mass axis.

Answer: From graph: Initial velocity (u) = 10 m/s, Final velocity (v) = 30 m/s, Time (t) = 8 s.
Acceleration: a = (v − u) / t = (30 − 10) / 8 = 20/8 = 2.5 m/s².
Force: F = ma = 10 × 2.5 = 25 N.
Force acting on the object = 25 N.

Answer: Mass = 50 g = 0.05 kg. Initial velocity (u) = 100 m/s. Final velocity (v) = 0 m/s. Distance (s) = 50 cm = 0.5 m.
Using: v² = u² + 2as ⇒ 0 = (100)² + 2a(0.5) ⇒ 0 = 10000 + a ⇒ a = −10000 m/s².
Force: F = ma = 0.05 × (−10000) = −500 N.
Stopping force = 500 N (opposite to direction of motion).

Answer: Speed = 108 km/h = 30 m/s. Initial velocity (u) = 0. Final velocity (v) = 30 m/s. Mass = 0.4 kg. Force = 800 N.
Using: F = ma ⇒ a = F/m = 800/0.4 = 2000 m/s².
Using: v = u + at ⇒ 30 = 0 + (2000)t ⇒ t = 30/2000 = 0.015 s.
Time of contact = 0.015 s.

Answer: Given: Mass of object, m = 2 kg. Initial velocity, u = 10 m s⁻¹. Force of friction = 7 N. Additional opposing force = 3 N.
Total opposing force: F = 7 N + 3 N = 10 N.
Using Newton’s second law: F = ma ⇒ a = F/m = 10 / 2 = 5 m s⁻².
Since the force is opposing the motion, acceleration is negative: a = -5 m s⁻².
Final velocity, v = 0 m s⁻¹.
Using the equation: v² = u² + 2as ⇒ 0 = (10)² + 2(-5)s ⇒ 0 = 100 – 10s ⇒ 10s = 100 ⇒ s = 10 m.
The object travels 10 m before coming to rest.

Answer: For the harrow: F = m₁a₁ ⇒ m₁ = F/a₁.
For the trolley: F = m₂a₂ ⇒ m₂ = F/a₂.
When both are together: Total mass = m₁ + m₂. Let resulting acceleration be a.
Then, F = (m₁ + m₂)a.
Substituting values of m₁ and m₂:
F = (F/a₁ + F/a₂)a ⇒ F = F(1/a₁ + 1/a₂)a ⇒ 1 = (1/a₁ + 1/a₂)a ⇒ a = 1/(1/a₁ + 1/a₂) ⇒ a = 1 / ((a₂ + a₁)/(a₁a₂)).
Therefore, a = (a₁a₂)/(a₁ + a₂). The resulting acceleration is a = (a₁a₂)/(a₁ + a₂).

Answer: According to Newton’s third law, the bar magnet and the compass needle exert equal and opposite forces on each other. However, motion depends not only on force but also on mass and support.

• The compass needle has very small mass, so even a small force produces noticeable acceleration and motion.
• The bar magnet has much larger mass, so the same force produces very little acceleration.
• Also, the bar magnet is usually held firmly in the hand or kept fixed, so it does not move.

Thus, although the forces are equal and opposite, the compass needle moves while the bar magnet appears not to move because the needle has much smaller mass and is free to rotate.

Answer: The SI unit of force is newton (written with lowercase ‘n’). Its symbol is N (uppercase). One newton is the force that produces an acceleration of 1 m/s² in a 1 kg object.

Answer: An object at rest remains at rest and an object in motion continues to move with constant velocity, unless a net (unbalanced) force acts upon it.

Answer: Two forces are called balanced when they are equal in magnitude and opposite in direction, resulting in zero net force. Balanced forces produce no change in the state of motion of an object.

Answer: Inertia is the natural tendency of an object to resist any change in its state of rest or of uniform motion in a straight line. The term was used by Isaac Newton.

Answer: Newton’s Second Law is expressed as F = ma, where F is net force in newtons, m is mass in kilograms, and a is acceleration in m/s². Acceleration acts in the direction of force.

Answer: A negative sign indicates the force acts in the direction opposite to the chosen positive direction. For example, −3000 N for a westward-moving car means the force is acting westward, opposing eastward motion.

Answer: The acceleration due to gravity near Earth’s surface is g = 9.8 m/s². For quick estimations, g = 10 m/s² is used. Importantly, g does not depend on the mass of the falling object.

Answer: Whenever object A exerts a force on object B, object B simultaneously exerts an equal and opposite force on object A. These action-reaction forces always act on two different objects.

Answer: Pulling the hand back increases the time for the ball to stop. By Newton’s Second Law, longer stopping time means smaller acceleration and therefore smaller force on the hand, reducing injury.

Answer: When two like poles of bar magnets face each other, magnet A repels magnet B with a magnetic force; simultaneously, magnet B repels magnet A with an equal and opposite magnetic force.

Answer: If a box moves at constant velocity, its acceleration is zero. By Newton’s Second Law (F = ma = m × 0 = 0), the net force on the box is zero. Applied force exactly balances friction.

Answer: When a person pushes the ground backward with their foot, friction acts in the forward direction on the foot, propelling the person forward. Without friction, the foot would slip backward.

Answer: The gravitational force on an object of mass m near Earth’s surface is F = mg, where g = 9.8 m/s². This force is also called the weight of the object, measured in newtons.

Answer: Using Newton’s Second Law for the combined system: a = F/(m₁ + m₂). Only external force F matters; internal forces (tension) cancel within the system and are not separately considered.

Answer: When climbing, legs push the trunk down. Friction pushes the person upward (Newton’s Third Law). A smooth trunk has less friction, so the upward force is smaller, making climbing much harder.

Answer: Action and reaction forces are equal and opposite but act on two different objects. When a paddle pushes water backward (action on water), water pushes the paddle forward (reaction on paddle). Since they act on different objects, they cannot cancel. The canoe moves forward as a result.

Answer: By Newton’s Third Law, the wall exerts an equal and opposite force of 50 N back on the boy. The boy typically does not move because the wall’s reaction force is transmitted through his body; friction from the floor on his feet provides another opposing force, keeping net force on him near zero.

Answer: Balanced Forces: Equal and opposite forces producing zero net force. Example – a book on a table (gravity balanced by normal force). The book remains stationary. Unbalanced Forces: Forces of unequal magnitude producing a nonzero net force. Example — one team pulling harder in tug of war. The rope accelerates toward the stronger team because the net force is nonzero.

Answer: In a collision, a car stops very abruptly – the passenger’s head decelerates very rapidly (large a), requiring a very large force (F = ma), which can cause fatal injuries. The airbag inflates quickly, increasing the stopping time. By F = m(Δv/Δt), larger Δt means smaller deceleration and therefore smaller force on the passenger’s head and chest, preventing serious injury.

Answer: A rocket engine burns fuel and expels hot exhaust gases downward at high speed (action). By Newton’s Third Law, these gases exert an equal and opposite force upward on the rocket (reaction). When this upward thrust is greater than the rocket’s weight (gravitational force downward), the net force is upward and the rocket accelerates skyward.

Answer: (a) Same direction: Net force = 8 + 5 = 13 N, in the direction of both forces. (b) Opposite directions: Net force = 8 − 5 = 3 N, in the direction of the larger (8 N) force. These results follow directly from the vector addition and subtraction of parallel forces.

Answer: If friction disappears, no net force opposes the object’s motion. By Newton’s First Law, an object in motion continues with constant velocity indefinitely in the absence of a net force. The object would never slow down or stop on its own. This is exactly what Galileo’s thought experiment predicted – remove all impediments, and a body moves forever on a horizontal plane.

Answer: When the gun fires, the explosion exerts a large force on the bullet, propelling it forward at very high speed (action on bullet). By Newton’s Third Law, the bullet exerts an equal and opposite force backward on the gun (reaction on gun). This backward force causes the gun to recoil. Because the gun’s mass is much greater than the bullet’s mass, its recoil acceleration is much smaller than the bullet’s forward acceleration.

Answer: From a = F/m: (a) If force is doubled (2F) at constant mass m: New acceleration = 2F/m = 2a ⇒ acceleration doubles. Force and acceleration are directly proportional. (b) If mass is doubled (2m) at constant force F: New acceleration = F/2m = a/2 ⇒ acceleration is halved. Mass and acceleration are inversely proportional.

Answer: When the sailor jumps forward toward the shore, they push the boat backward with their feet (action on boat). By Newton’s Third Law, the boat exerts an equal and opposite force on the sailor (reaction on sailor, which helps propel them forward). Since no anchoring force holds the boat, it moves backward – away from the shore – in the direction opposite to the sailor’s jump.

Answer:
Newton’s First Law (Law of Inertia): An object at rest remains at rest and an object in motion continues moving with constant velocity unless a net force acts on it. Example: Passengers lurch forward when a bus brakes suddenly — their bodies resist the change in motion due to inertia.
Newton’s Second Law: When a net force acts on an object, it accelerates in the direction of that force. F = ma. Example: A loaded cart needs more force than an empty cart to achieve the same acceleration.
Newton’s Third Law: Every action has an equal and opposite reaction on a different object. Example: Jumping is possible because feet push the ground down (action) and the ground pushes the body up (reaction).

Answer: Friction is a contact force that opposes relative motion between surfaces. It always acts opposite to the direction of motion. Its magnitude depends on the nature of surfaces in contact — rougher surfaces produce more friction, smoother surfaces produce less.
Useful effects: 1. Enables walking — friction from ground propels us forward. 2. Allows vehicles to brake safely. 3. Grooves on tyres and shoe soles increase grip.
Harmful effects: 1. Causes wear and tear in machine parts. 2. Generates unwanted heat, reducing engine efficiency. 3. Wastes energy — vehicles must continuously overcome friction.
Friction is reduced using lubricants, ball bearings, polished surfaces, streamlined shapes and magnetic levitation.

Answer:
Phase 1 (0–5 s): Using v = u + at ⇒ a = (10−0)/5 = 2 m/s². F = ma = 1500 × 2 = 3000 N eastward. The car accelerates — net forward force acts.
Phase 2 (5–10 s): Velocity is constant ⇒ acceleration = 0. F = ma = 1500 × 0 = 0 N (no net force). Newton’s First Law applies — constant velocity requires zero net force.
Phase 3 (10–15 s): a = (0−10)/5 = −2 m/s². F = 1500 × (−2) = −3000 N. Negative sign indicates force acts westward (opposing motion) — braking force decelerates the car to rest.

Answer: A rocket engine expels hot gases downward at high speed (action). By Newton’s Third Law, these gases push the rocket upward with equal force (reaction). When this upward thrust exceeds the rocket’s weight, the net force is upward and the rocket lifts off.
Chandrayaan-3 Vikram Lander used retro-firing — the engine fired in the direction of motion, producing a backward reaction force that slowed the lander to the precise velocity needed for a safe soft landing near the Moon’s south pole.
Balloon Activity: Releasing the balloon forces air out backward (action). The air pushes the balloon forward (reaction) — an exact small-scale model of rocket propulsion.

Answer:
Activity 6.3 (constant mass, varying force): Doubling the hanging cup’s mass doubled the cart’s acceleration — proving a ∝ F at constant mass.
Activity 6.4 (constant force, varying mass): Doubling the cart’s mass halved its acceleration — proving a ∝ 1/m at constant force.
Combining both: a ∝ F/m ⇒ F = ma.
Common Principle — Cricket Catch and Airbag: Both use the relationship F = m(Δv/Δt). The change in velocity (Δv) is fixed. By increasing the stopping time (Δt), acceleration and therefore force are reduced. 1. Fielder pulls hand back → more time ⇒ less force → no injury. 2. Airbag inflates → more stopping time ⇒ less force on passenger → prevents fatal injury.