Understanding the Difference Between Mass and Weight | Physics Explained

Mass and Weight

Key Definitions

MASS AND WEIGHT

Mass

Mass: Mass is the basic property of a body. Mass of a body is defined as the quantity of matter contained in the body. Its SI unit is kilogram (kg).

Weight

Weight: Weight of a body is defined as the gravitational force exerted on it due to the Earth’s gravity alone.

Calculating Weight

The relationship between weight, mass, and gravity is expressed by the following formula:

Weight = Gravitational Force

mass (m) × acceleration due to gravity (g)

g = acceleration due to gravity for Earth (at sea level) = 9.8 m s^–2.

Properties of Weight

Weight is a vector quantity. Direction of weight is always towards the centre of the Earth. SI unit of weight is newton (N). Weight of a body varies from one place to another place on the Earth since it depends on the acceleration due to gravity of the Earth (g) weight of a body is more at the poles than at the equatorial region.

Example: Weight on Earth vs. The Moon

The value of acceleration due to gravity on the surface of the moon is 1.625 ms^–2. This is about 0.1654 times the acceleration due to gravity of the Earth. If a person whose mass is 60 kg stands on the surface of Earth, his weight would be 588 N (W = mg = 60 × 9.8). If the same person goes to the surface of the Moon, he would weigh only 97.5 N (W = 60 × 1.625). But, his mass remains the same (60 kg) on both the Earth and the Moon.

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Context: 10th Science : Chapter 1 : Laws of Motion : Mass and Weight

Understanding Gravitation: Newton's Law, Acceleration Due to Gravity (g), and Earth's Mass

Gravitation

Newton's Universal Law of Gravitation

GRAVITATION

This law states that every particle of matter in this universe attracts every other particle with a force. This force is directly proportional to the product of their masses and inversely proportional to the square of the distance between the centers of these masses. The direction of the force acts along the line joining the masses.

Force between the masses is always attractive and it does not depend on the medium where they are placed.

Let, m₁ and m₂ be the masses of two bodies A and B placed r metre apart in space

Force F ∝ m₁ × m₂

F ∝ 1/ r²

On combining the above two expressions

Where G is the universal gravitational constant. Its value in SI unit is 6.674 × 10^–11 m²kg^–2.

2. Acceleration due to gravity (g)

When you throw any object upwards, its velocity ceases at a particular height and then it falls down due to the gravitational force of the Earth.

The velocity of the object keeps changing as it falls down. This change in velocity must be due to the force acting on the object. The acceleration of the body is due to the Earth’s gravitational force. So, it is called as ‘acceleration due to the gravitational force of the Earth’ or ‘acceleration due to gravity of the Earth’. It is represented as ‘g’. Its unit is m s^–2

Mean value of the acceleration due to gravity is taken as 9.8 m s^–2 on the surface of the Earth. This means that the velocity of a body during the downward free fall motion varies by 9.8 m s^–1 for every 1 second. However, the value of ‘g’ is not the same at all points on the surface of the earth.

3. Relation between g and G

When a body is at rests on the surface of the Earth, it is acted upon by the gravitational force of the Earth. Let us compute the magnitude of this force in two ways. Let, M be the mass of the Earth and m be the mass of the body. The entire mass of the Earth is assumed to be concentrated at its centre. The radius of the Earth is R = 6378 km (= 6400 km approximately). By Newton’s law of gravitation, the force acting on the body is given by

Here, the radius of the body considered is negligible when compared with the Earth’s radius. Now, the same force can be obtained from Newton’s second law of motion. According to this law, the force acting on the body is given by the product of its mass and acceleration (called as weight). Here, acceleration of the body is under the action of gravity hence a = g

4. Mass of the Earth (M)

Rearranging the equation (1.14), the mass of the Earth is obtained as follows:

Mass of the Earth M = g R²/G

Substituting the known values of g, R and G, you can calculate the mass of the Earth as

M = 5.972 × 10²⁴ kg

5. Variation of acceleration due to gravity (g):

Since, g depends on the geometric radius of the Earth, (g ∝ 1/R²), its value changes from one place to another on the surface of the Earth. Since, the geometric radius of the Earth is maximum in the equatorial region and minimum in the polar region, the value of g is maximum in the polar region and minimum at the equatorial region.

When you move to a higher altitude from the surface of the Earth, the value of g reduces. In the same way, when you move deep below the surface of the Earth, the value of g reduces. (This topic will be discussed in detail in the higher classes). Value of g is zero at the centre of the Earth.

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10th Science : Chapter 1 : Laws of Motion : Gravitation