Potential Energy of a System of Charges: Overview, Questions, Preparation

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Electromagnetism Magnetic Effect of Electric Cur...Electromotive Force Curie Weiss Law Planck Equation Magnetic Force The Solenoid and the Toroid Force between two parallel curr...Moving Coil Galvanometer Torque on current loop, magneti...Potential Energy of a System of...Electrostatics of Conductors Parallel Plate Capacitor Combination of Capacitors

Dhanya B

Updated on Nov 7, 2023 17:13 IST

Potential Energy of a System of Charges: The potential energy of a system of charges in an NCERT Class 12 Physics context typically relates to the electrostatic potential energy associated with these charges. This potential energy is a measure of the energy stored within a system of charged particles due to their mutual interactions. It is calculated using Coulomb's law, which describes the electrostatic force between point charges.

Table of Contents

Potential Energy Formula
FAQs on Potential Energy of a System of Charges

Potential Energy Formula

The formula for the potential energy (U) of a system of charges is as follows:

U = k (q₁ q₂) / r

Where:

U is the potential energy.

k is Coulomb's constant, approximately equal to 9 x 10⁹ N·m²/C² in SI units.

q₁ and q₂ are the magnitudes of the charges of the two point charges in the system.

r is the distance between the charges.

The potential energy is a measure of the work done in assembling the system of charges from infinity (where the potential energy is defined as zero) to their current positions. When like charges (q₁ and q₂ with the same sign) are brought closer together, the potential energy becomes more positive, indicating that energy has been added to the system. On the other hand, when opposite charges (q₁ and q₂ with different signs) are brought closer together, the potential energy becomes more negative, indicating that work has been done to separate them.

In summary, in Class 12 physics, the potential energy of a system of charges is a measure of the energy associated with their electrostatic interactions, and it depends on the magnitudes of the charges and the distance between them. This concept is important in understanding the behaviour of electric fields, electric potential, and the principles of electrostatics.

FAQs on Potential Energy of a System of Charges

Q. A charge of 8 mC is located at the origin. Calculate the work done in taking a small charge of –2 × 10–9 C from a point P (0, 0, 3 cm) to a point Q (0, 4 cm, 0), via a point R (0, 6 cm, 9 cm).

A . Charge located at the origin O, q=8 mC= 8 C

Magnitude of a small charge, which is taken from point P to Q, = -2 C

Pont P is at a distance, = 3 cm = 0.03 m from origin, along Z axis

Point Q is at a distance, = 4 cm = 0.04 m from origin, along y axis

Potential at point P, =

Potential at point Q, =

= permittivity of free space = 8.854

Work done, W = = =

= (-0.1438) = 1.198 J

Q. A cube of side b has a charge q at each of its vertices. Determine the potential and electric field due to this charge array at the centre of the cube.

A. Length of the side of a cube = b

Charge at each vertices= q

d = diagonal of each face, d = = b

l = length of the solid diagonal, l = = b

If r is the distance from the centre of the cube to its corner, then r = l/2 =

The electric potential (V) at the centre of the cube is due to the presence of eight charges at the vertices.

V = = =

Therefore, the potential at the centre of the cube is

The electric field at the centre of the cube, due to eight charges, gets cancelled, since the charges are distributed symmetrically. The electric field is zero at the centre.

Q. Two tiny spheres carrying charges 1.5 μC and 2.5 μC are located 30 cm apart. Find the potential and electric field: (a) at the mid-point of the line joining the two charges, and (b) at a point 10 cm from this midpoint in a plane normal to the line and passing through the mid-point.

A. Two charges are at point A and B. O is the midpoint of line joining A & B

Magnitude of charge at point A, = 1.5 = 1.5 and

at point B, = 2.5

Distance between A & B, d = 30 cm = 0.3 m