Newton's Laws of Motion PDF

Summary

This document explores Newton's Laws of Motion, covering concepts like inertia, momentum, and force. It provides definitions and mathematical explanations of each law, and includes examples for better understanding. The text is suitable for secondary school students studying physics.

Full Transcript

NEWTON’S LAWS OF MOTION

Motion can be defined as the relative change in the state of direction of a body with
respect to force of reference. According to Newton the motion, of a body in a straight
line can be summarized in three basic laws.
Newton’s first law of motion: This states that a stationary body or a body moving will
continue to maintain its state of rest or uniform motion unless acted upon by an
external force.
In other words, a body at rest will remain so if no force acts on it. The same is true for
bodies in motion. It will be so continuously if no unbalanced force acts on it to slow it
down to a stop. Such unbalances forces which tends to bring a moving body to a halt is
the force of gravity or frictional force, otherwise a body once set in motion will continue
with constant velocity.

The tendency of a body to remain at rest or uniform motion on a straight line in the
absence of applied forces is known as INERTIA.

For Newton’s first law, we say that inertia is inherent in bodies at rest. That law also
explains what force does but it does not suggest how it is measured. Newton’s first law
is also known as the law of inertia.

Newton’s second law of motion: This states that the rate of change of momentum is
directly proportional to the impressed force and takes place in the direction of the
force.

MATHEMATICALLY,
Force α rate of change of momentum
F α ΔP
𝐶ℎ𝑎𝑛𝑔𝑒 𝑖𝑛 𝑚𝑜𝑚𝑒𝑛𝑡𝑢𝑚
Fα
𝑡𝑖𝑚𝑒 𝑡𝑎𝑘𝑒𝑛 𝑓𝑜𝑟 𝑡ℎ𝑒 𝑐ℎ𝑎𝑛𝑔𝑒

𝑚𝑣 −𝑚𝑢
i.e. F α
𝑡
Note: momentum = mass x velocity
= mv
Where m = mass in kg; v = final velocity in m/s; u = initial velocity in m/s; t = time taken
for the change in seconds; F = force in Newton.
𝑣−𝑢
But; Acceleration, a =
𝑡

𝑚(𝑣−𝑢)
Thus; F =
𝑡

F = Kma (Where k = constant)
The unit of force is chosen so that k = 1
:. F = ma
The unit of force is Newton (N) which gives a mass of 1kg and an acceleration of 1 m/s2.
𝑚(𝑣−𝑢)
F=
𝑡

Ft = m (v – u)
The product “Ft” is known as the IMPULSE of the force.

:. I = Ft = m(v-u) = change in momentum

Impulse is measured in Newton-seconds (Ns). This is also the unit of momentum.
Momentum is measured in kgm/s. from Newton’s second law, it can be seen that:
i. force is the product of mass and acceleration.
ii. force is the rate of change of momentum.

Newton’s third law of motion: This states that to every action there is always an equal
and opposite reaction. This implies that action and reaction are equal but opposite in
direction. It also implies that the mutual actions of two bodies upon each other are
always equal and directed to contrary parts.

This implies that when a body, A exerts a force F A on a body B, the body B in turn exerts
a force FB on body A. The forces FA and FB are equal in magnitude and opposite in
direction. Since force is a vector, then
FA = - FB
FA gives the action while FB gives the direction.

Example 1: A ball of mass 0.3kg moving at a velocity of 20m/s is suddenly hit by a force
of 5N for a time of 0.03 seconds. Find its new velocity.
SOLUTION:
From Newton’s second law
𝑚(𝑣−𝑢)
F=
𝑡
𝐹𝑡
V=u+
𝑡

5 𝑥 0.03
= 20 +
0.3

= 20.5 m/s

Example 2: When taking a penalty kick, a footballer applies a force of 30 N for a period
of 0.05 seconds. If the mass of the ball is0.075kg, calculate the speed with which the ball
moves off.
SOLUTION:
𝑚(𝑣−𝑢)
F=
𝑡
 0.075 𝑥 𝑣
30 =
0.05
V = 20 m/s

APPLICATIONS OF NEWTON’S THIRD LAW OF MOTION
1. Rocket propulsion: A rocket is propelled by the ejection of a portion of its mass to the
rear. The forward force on the rocket is the reaction to the backward force on the
ejected materials.
2. Recoil of a gun: When a bullet is shot from gun, the person firing experiences
backward impact.
3. Jet engines: A fired engine burns by smoothing gas downward from the tail of the
rocket at high.
4. why walking is possible: when a person pushes his or her foot against the ground, the
ground in turn also pushes or exerts a force which I equal and opposite to the push on
the person.

CONSERVATION OF LINEAR MOMENTUM
Momentum is defined as the product of the mass of a body or particle and the velocity
in a given direction.
Momentum is a vector quantity, measured in Kgm/s.

PRINCIPLE OF CONSERVATION OF LINEAR MOMENTUM
The principle of conservation of linear momentum states that if two or more bodies
collide in a closed system, the total momentum before and after collision remains
unchanged.
Assume a body of mass M1 and acceleration a1 moving towards another body M2 and
acceleration a2; and their forces are equal and opposite. Then from Newton’s third law:
F1 = - F2
From Newton’s second law F = ma, hence
M1a1 = M2a2
Recall, acceleration, a, is given by:
𝑽−𝑼
a=
𝒕
Therefore,
𝑉1− 𝑈1 𝑉2 − 𝑈2
M1 = - M2
𝑡 𝑡
M1 (V1 – U1) = - M2 (V2 – U2)
:. M1V1 – M1U1 = -M2V2 +M2U2
M1V1 + M2V2 = M1U1 + M2U2
Where U = Initial velocity before collision
V = Final velocity after collision
t = constant time of the body during collision
TYPES OF COLLISON
1. ELASTIC COLLISION: If after two bodies had collided, their kinetic energy K.E both
before collision and after collision is the same, then, such collision is perfectly elastic. In
such occasion both momentum and energy are conserved. In such situation the bodies
moves with different velocities after collision.
Consider two bodies of masses M1 and M2 moving with initial velocities u1 and u2 after
collision, we arrive at the following equations if collision is perfectly elastic:
M1U1 + M2U2 = M1V1 + M2V2
For their kinetic energy
½ M1U12 + ½ M2U22 = ½ M1V12 + ½ M2V22
2. INELASTIC COLLISION: Conversely, in inelastic collision, the kinetic energy
decreases after collision, but the momentum is conserved all the same. In such case, the
colliding bodies stoic together and move in one direction (direction of the body with the
greatest momentum). Meaning:
V = V1 = V2
Hence,
M1U1 + M2U2 = (M1 + M2) V
The kinetic energy of the system before collision and after collision is given by
E.K1 = ½ M1U12 + ½ M2U22
After collision
E.K2 = ½ M1V12 + M2V22 = ½ (M1 + M2) V2
Since for a completely inelastic collision, the kinetic energy (E.K) before collision is
greater than the kinetic energy (E.K) after collision.

Example 1: A ball of mass 200g travelling with a velocity of 100ms-1 collides with
another ball of mass 800g moving at 50ms-1 in the same direction. If they stick together,
what will be their common velocity?
Solution
M1U1+ M2U2 = (M1 + M2) V
V = M1 U1 + M2 U2
M1 + M2
= (0.2)100 + (0.8)50
0.2 + 0.8
= 20 + 40
1
V = 60ms-1
E.K before collision = ½M1U12 + ½ M2U22
= ½ (0.2)(100)2 + ½(0.8)(50)2
= 1000 + 1000
= 2000J
E.K After collision = ½(M1 + M2) V2
= ½(0.2 + 0.8)(60)2
= ½(1) 3600
= 1800J
Loss in energy = E.K before – E.K after
= 2000 - 1800
= 200J (This however, is for inelastic collision).
Example 2: A body of mass 4.2kg moving with velocity of 10ms-1 due east, hits a
stationary body of mass 208kg. If they stick together after collision and move with a
velocity V due east, Calculate the value of V.
Solution
M1V1 + M2 U = (M1 + M2) V
(4.2)10 + 2.8(0) = (4.2 + 2.8) V
42 = 7V
V = 6ms-1
E.k before collision = ½M1V12
= ½ (4.2) (10)2
= ½ (4.2)(100)
= ½ (4.2)(100)
= 420/2 = 210
E.k after collision = ½ (M1 + M2) V2
= ½ (4.2 + 2.8) (6)2
= ½ (7) 36
= 126J
E.k loss = ½ M1V12 - ½ (M1 + M2)
= 210 – 126
= 84J

Example 3: A ball of mass 6.0kg moving with a velocity of 10ms-1 collides with a 2.0kg
ball moving in the opposite direction with a velocity of 5.0ms-1. After the collision the
two balls coalesce and move in the same direction.
Calculate the velocity of the composite body.
Solution
M1V1 – M2V2 = (M1V2) V
6(10) – 2(5) = (6 + 2) V
60 – 10 = 8V
50 = 8V
V = 50
8
= 6.25ms-1
E.K before collision = ½ M2V12 + ½ M2V22
= ½ (6) (10)2 + ½ (2) (5)2
= ½ [600 + 50]
= ½ (650)
= 325J
E.K after collision = ½ (V1 + M2) V2
= ½ (6 + 8) (6.25)2
= 273.4J
E.K loss = 325 – 273.4
= 51.6J