The concept of Force

A force is an interaction that causes a change. In mechanics, a force is an interaction that causes a change in velocity (an interaction that causes acceleration).

 

The Concept of Force

Explain the concept of force

For a better understanding of this concept, let’s ask ourselves the following question:

1. What causes/makes a body at rest to move?

2. What causes the same body in motion to stop?

The answer to these questions is, of course, that a force is required to do so. Here, an applied force to a body can cause the body at rest to move, or if already moving, a body application of force can do the following when applied to a body.

1. Force can cause a change in the way the object moves

2. Change its size or shape

3. Change the direction in which an object is moving

A force is defined as a push or pull experienced by an object. The force is usually described in terms of its size (magnitude) and direction.

 

The SI unit of Force

State the SI unit of force

The SI unit of force is Newton (N).

A Newton (1N) can be defined as the amount of force required to give a mass of one kilogram (1kg) an acceleration of 1m/s².

Measuring Instrument (Device)

The instrument that is used to measure the amount of force that is exerted on an object is called a spring balance.

A spring balance can be used to measure small forces. It consists of a coiled spring fixed to the other end with a hook at the other end. The body upon which the force acts is attached to the hook. The distance through which the spring is stretched is directly proportional to the force applied by the balance.

A pointer is attached to the spring, and the force is indicated on a calibrated scale.

 

Fundamental Types of Forces

Identify fundamental types of forces

There are two main types of forces, namely:

1. Fundamental forces

2. Non-fundamental forces

Fundamental Forces

Fundamental forces are the basic forces in nature that cannot be explained by the action of another force.

There are four types of fundamental forces. These include:

1. The force of gravity

2. The electromagnetic force

3. The strong nuclear force

4. The weak nuclear force

Force of gravity (weight)

The force of gravity is the pull by which the Earth, the moon and other very large bodies attract other objects towards themselves. It is commonly referred to as the weight of the object that is attracted.

All objects on Earth experience a force of gravity that is directed downwards towards the centre of the Earth. The Earth’s gravitational pull is so great that it can hold most things firmly on the ground.

In mechanics, a freely falling body in the air moves down irrespective of its mass. This is due to the force of gravity.

Example 4

A fruit falls from a tree because the Earth exerts a gravitational force on it. The force of gravity on the Earth is always equal to the weight of the object (body).

Force of gravity, W = mass (m) x gravitational acceleration (g).

W= mg

Where the acceleration due to gravity on Earth, g = 9.8m/s²

Conclusion, we can say that the force of gravity has the following properties.

1. It pulls (attracts) objects towards the centre of the Earth.

2. It is directly proportional to the mass of the object. This means that the greater the mass, the greater the pull of gravity.

3. It is strong when the mass is closer to the centre of the Earth.

NB: It should be noted that the weight of an object is directly related to its Mass.

Weight, W = mass x g = mg

The g above has two meanings:

1. It is the gravitation field strength (10n/Kg)

2. It is the acceleration of free fall (10m/s²

Electromagnetic force

This force includes both electric and magnetic forces. It is relatively strong.

Example 2

Examples where electromagnetic forces are involved include:

1. In the formation of molecules of a substance. Atoms attract each other to form molecules. This is due to electromagnetic force.

2. In two parallel wires carrying current. If places are near each other, the electromagnetic force acts on the wires.

Strong nuclear force

This is the force which holds the constituents (subatomic particles) of the atomic nucleus. It acts within the nucleus of the atom.

Weak nuclear force

This is the force which appears only in certain nuclear processes.

The Properties of Each Type of Fundamental Force

Describe the properties of each type of fundamental force

Properties of gravitational forces

The following are the properties of the gravitational force

It always attracts objects.

It is the weakest force among the four basic forces.

It is a central force (gravitational force between two objects acts along the line joining the centres of the objects.

It operates over very long distances.

Properties of electromagnetic force include

It may be attractive or repulsive in nature

It is a central force

It is stronger than the gravitational force

It is also a long-range force (operates over a very long distance)

Properties of a strong nuclear force:

It is basically an attractive force

It is a non-central force (does not act at the centre)

It is stronger than the gravitational force

It is a short-range force that is it operates only up to a distance of the order of 10^-14m

Properties of the weak nuclear force

It is much stronger than the gravitational force, but weaker than the strong nuclear force and electromagnetic force

It acts on small ranges of up to 10^-17m

Activity 1

CLASS ACTIVITY

1. Define the term force and give its SI unit.

2. Mention four fundamental types of force that you know.

3. Define the following terms: Force of gravity, Strong nuclear force, Electromagnetic force.

4. A body has a mass of 40kg. Find its weight.

 

The Effects of Forces

Identify the effects of forces

A force acting on an object may cause the object to change shape, to start moving, to stop moving, to accelerate or to decelerate.

When two objects interact with each other, they exert a force on each other; the forces are equal in size but opposite in direction.

Resultant force

The forces acting on an object can be replaced with a single force that causes the object to behave in the same way as all the separate forces acting together did. This one overall force is called the resultant force.

If the resultant force acting on an object is ZERO, then:

The object will remain stationary if it was stationary when the resultant force became zero.

Move at a constant (steady) speed in a straight line if it were moving when the resultant force became zero.

If the resultant force acting on an object is NOT ZERO, then:

The object will accelerate or decelerate (speed up or slow down).

The Effects of Forces on Materials

Justify the effects of forces on materials

Forces have several effects on materials. Some of the effects of forces are as follows:

Stretching – This effect can be seen when the object is pulled tightly to make it longer or extended.

Compression and restoring – Compression occurs when an object is pressed to reduce its size. The object can be returned to its original size by a force known as the restoring force. The restoring force is the force which tends to return the object to its original shape and size.

Torsion – Takes place when the object is twisted, for example, twisting a flat bar.

Attraction - The Attraction force is the force that pulls objects toward each other. For example, the force between pieces of magnets or between magnets and objects like iron.

Viscosity – Also known as viscous force, is a resistance between liquids or gases. For example, water flows easily because it is less viscous, cooking oil flows with resistance than water, and honey flows with more resistance than cooking oil. That means water has low viscosity, cooking oil has higher viscosity than water, and honey has the highest viscosity than cooking oil. High-viscosity liquids like honey tend to resist the flow of objects through them. For example, it is difficult for an object to flow through honey than through water.

Air resistance - Air resistance is the force that resists the movement of an object through the air. It is an example of viscosity. Air resistance depends on three things, which are the size and shape of objects moving in the fluid, the speed through the fluid, and the density of the fluid.