Force And Laws Of Motion

Since, the object will be moving around the centre of the earth and being on the surface of the earth. So, in no ways it would go away from the earth.

Since, Newton’s third law states that for every action there is an equal and opposite reaction which means that in every interaction there is a pair of forces acting on the two interacting objects. The size of the forces on the first object equals the size of the force of the second object.

A goalkeeper in a game of football pulls his hands backwards after holding the ball shot at the goal which increases the time span for the momentum to be reduced to zero which hence reduces the force.

Since, inertia is the tendency of an object to do nothing or to remain unchanged in its state of motion or rest.

Thus, the inertia of an object tends to cause the object to resist any change in its state of motion.

As it is only possible when the train is accelerating, the coin exist the inertia of motion in the forward direction and hence when it is tossed it falls backward.

Therefore, a passenger in a moving train tosses a coin which falls behind him. It means that motion of the train is accelerated.

As it exist the inertia of motion and according to first law an object continues to be in its state of rest or motion unless an external force is applied to it.

According to the law of conservation of momentum which states that for two objects colliding in an isolated system the total momentum before and after the collision is equal.

Since, the water exist the inertia of motion in the forward direction so when the brakes are applied the inertia of water resist the brakes applied. Hence, it moves forward.

Inertia depends upon mass of an object. Since, steel has greatest density and greatest mass therefore, it has the highest inertia. It is given that all have the same volume therefore, the object with large volume will have more mass. We know that the density of the steel is greatest of all thus steel would have higher energy.

Yes. Both the balls will start rolling due to inertia of motion and they roll in the direction in which the train is moving. Due to the application of the brakes, the train comes to rest but due to inertia the ball tries to remain in motion, therefore, they continue to roll. The two balls will not roll with the same speed since, the masses of the ball are not same, therefore, the inertial force are also not same on both the balls thus the ball will move with difference speed.

As both the bullets are said to be identical and are fired with the same force, therefore, as per Newton’s third law of motion, every action has an equal and opposite reaction; same force will be applied on both the rifles. As the same amount force is applied on both the rifles, the lighter rifle will move more quickly in the backward direction causing serious injury to the shoulder.

A horse continues to apply a force to move a cart with a constant speed so as to overcome the force of friction between the cart and the ground. Once the cart start moving, the force of friction comes into action. It starts working on the wheels of the cart in the direction opposite to the direction of the motion of the cart. So, the horse has to apply a continuous force in the forward direction to maintain constant speed.

The law of conservation of momentum is applicable to isolated system. An isolated system is a system that is free from the influence of a net external force. In the given example, the change in velocity is due to the gravitational force of earth. This is an external force. Therefore, it is not an example of conservation of momentum.

Given, m = 50g

F =?

We know, Force = mass × acceleration

= * 10 = 0.5 N

The velocity of the ball zero time is 80ms^-1. It decelerates due to the friction of the floor with itself and comes to rest after 8 seconds.

a = =

= -10m/s²

The negative sign indicates that the frictional force exerted opposes the motion of the ball. Now, using Newton’s relation,

F = m× a

= × -10

= -0.5 N

Given, The initial mass m₁ = M

Initial force, f₁ = F

Given that, new mass m₂ = M + M = 2M and new force f₂ =

Now, F = m×a

a =

Initial acceleration (a₁) =

New acceleration (a₂) =

Change in acceleration = = = 4

Therefore, = 4

= a₂

Thus, the new acceleration will be one–fourth of the old acceleration.

The initial momentum of both of them is zero but when one friend a ball of 2kg to other Newton’s third law of motion comes into action. Therefore, when one friend throws the ball to other he exerts a force on the ball and receives an equal and opposite force. In order to conserve the momentum, the one who throws the ball will move backward changing his initial position.

Now the other friend catches the ball, Law of conservation of momentum comes into action. In this case the momentum of the ball before catching and after catching will be equal. Therefore, the second will experience a net force after catching the ball and therefore will move backwards in the direction of the force. Thus, the separation between them will increase.

The working of the rotation of sprinkler is based on third law of motion. As the water comes out of the nozzle of the sprinkle, an equal and opposite reaction force comes into play so the sprinkler starts rotating.

(i) Given,

m = 10g = kg

u = 10³ m/s

v = 0, s = 5cm = m

v² – u² = 2as

0 – (10³)² = 2 × a ×

-(10³) × (10)³ =

a = (-1000 × ) × 100

= -10⁷ ms^-2

F = ma

= 1/100x - 10⁷

= -10⁵ N

(ii) v = u +at

0 = (10³) – 10⁷ × t

t =

t = 10^-4s

We know,

Force = mass× acceleration

Unit of mass = kg

Unit of acceleration = m/s²

Therefore, unit of force = kg m/s²

1 kg m/s² = 1 N

Given, F = 5 N, mass = m₁

Acceleration, a = 8 m/s²

F = m × a

m₁ = kg

Similarly, given F = 5N

Mass = m₂

a = 24 m/s²

5 = m₂ × 24 m/s²

m₂ = kg

If both the masses are tie together,

Total mass = kg

Now, acceleration for mass kg

F = 5 N

F = m × a

a = = 6 m/s²

Momentum is the product of mass and velocity of an object. It is a vector quantity.

The SI unit of momentum is kg m/s.

The force acting on an object equals the rate of change of momentum of the object.

Force = rate of change in momentum

mv = constant

The change in momentum formula is given as:

p = mv

Therefore, when mass m is fixed, p is proportional to v.

Similarly, when v is constant, p is proportional to m.

Therefore, and graph are both straight lines.