Dimensional Formula of Acceleration Due To Gravity

Dimensions of the physical quantity are the power to which the base quantities are raised to represent that quantity. 

Dimensional Formula: 

The Dimensional Formula of any physical quantity is that expression that represents how and which of the base quantities are included in that quantity. 

It is written by enclosing the symbols for base quantities with appropriate power in square brackets i.e ( ).

E.g: Dimension Formula of Mass is: (M)

Dimensional Equation: 

The equation obtained by equating a physical quantity with its Dimensional Formula is called a Dimensional equation. 

Application of Dimensional Analysis: 

1. To convert a physical quantity from one system of the unit to the other:

It is based on a fact that the magnitude of a physical quantity remains the same whatever system is used for measurement i.e magnitude = numeric value(n) multiplied by unit (u) = constant

n1u1= n1u2

2. To check the Dimensional correctness of a given physical relation: 

If in a given relation, the terms of both sides have the same Dimensions, then the equation is dimensionally correct. This concept is best known as the principle of homogeneity of dimensions. 

3. To develop a relationship between different given physical quantities: 

Using the principle of homogeneity of dimension, the new relation among physical quantities can be derived if the dependent quantities are known. 

Limitation of this Method:

1. This method can be used only if dependency is of multiplication type. The Formula containing exponential, trigonometric, and logarithmic functions can not be derived using this method. The Formula containing more than one term which is added or subtracted likes \[s = ut + \frac{1}{2} at^{2}\] also cannot be derived.

2. The relation derived from this method gives no information about the dimensionless constants. 

The Dimension of Acceleration Due to Gravity:

The Dimensional Formula of Acceleration Due To Gravity is written as \[M^{0}L^{1}T^{-2}\].

Where M = Mass; L = Length; T = Time all these units are standard units of a given quantity. 

Derivation of Dimension Formula of Acceleration Due to Gravity:  

We know that Force = Mass × Acceleration due to Gravity

∴ Acceleration due to Gravity (g) = Force × \[Mass^{-1}\] takes it as an equation . . . . . (1)

The Dimensional Formula of the Mass =\[M^{1}L^{0}T^{0}\] takes it as an equation. . . (2)

At the same time, the Dimensional Formula of Force = \[M^{1}L^{1}T^{-2}\] takes it as an equation . . . . (3)

On putting equations (2) and (3) in equation (1) we get,

Acceleration due to Gravity = Force × \[Mass^{-1}\] Or, g = \[M^{1}L^{1}T^{-2}\] * \[M^{1}L^{0}T^{0}\] = \[M^{0}L^{1}T^{-2}\].

Dimensional representation of Acceleration due to Gravity is Dimensionally given as 

\[M^{0}L^{1}T^{2}\].

Acceleration Due to Gravity:

Acceleration due to gravitational force in an object is called Acceleration due to Gravity. S.I unit of Acceleration due to Gravity is written as \[\frac{m}{s^{2}}\]. It is a vector quantity as it has both magnitude and direction. It is denoted by the symbol g and its value is approximately 9.80665  \[\frac{m}{s^{2}}\]. However, the actual Acceleration of a body in free fall varies with location.

Formula for Acceleration due to Gravity is: \[G = \frac{k. M1. M2}{r^{2}}\].

Right-Hand Rule

The Right-Hand Rule describes the magnetic fields and the forces that they exert on moving charges and conveys a simple method to remember the directions that things are supposed to point. One of the most important things to remember in the Right-Hand Rule is to always avoid using the Left Hand instead of the Right Hand which is common practice among many students.

If the charges are still in an environment, they are unchanged by magnetic fields. When the charges start to move, the magnetic field pushes on the charges.

Faraday’s law of electromagnetic induction states that when a moving electrical conductor is kept inside a magnetic field, a current will get induced in it. If that electrical conductor is strongly dragged inside the magnetic field, there is an association between the direction of the involved force, magnetic field, and the current. Fleming’s Right-Hand Rule specifies this relation between these 3 directions.

To perform the Right- Hand Rule, the following instructions should be followed-

1. Grab the Right-Hand forefinger, middle finger, and thumb at Right angles to each other. 

2. Taking that the forefinger represents the direction of the magnetic field, the thumb will point in the direction of motion or involved force, 

3.  The middle finger will then be in the direction of the generated current.

Left Hand Rule

When a given current-carrying conductor is put in an exterior magnetic field, the conductor encounters a force perpendicular to the field and the current flow’s direction.

To perform the Right- Hand Rule, the following instructions should be followed-

1. Grab out the Left Hand with the forefinger, the second finger, and thumb forming Right angles to each other. 

2. The forefinger will represent the direction of the field and the second finger will represent the direction of the current.

3.  The thumb will represent the direction of the force.