A capacitor having a capacitance of 100μF is charged to a potential d

1.	A capacitor having a capacitance of 100μF is charged to a potential difference of 24V. The charging battery is disconnected and the capacitor is connected to another battery of emf 12V with the positive plate of the capacitor joined with the positive terminal of the battery, (a) Find the charges on the capacitor before and after the reconnection. (b) Find the charge flown through the 12V battery, (c) Is work done by the battery or is it done on the battery? Find its magnitude, (d) Find the decrease in electrostatic field energy, (e) Find the heat developed during the flow of charge after reconnection.
Answer» (a) Before reconnection C = 100μf V = 24V q = CV = 2400μc (Before reconnection) After connection When C = 100μf V = 12V q = CV = 1200μc (After connection) (b) C = 100, V = 12V ∴ q = CV = 1200v (c) We know V = W/q W = vq = 12 × 1200 = 14400J = 14.4mJ The work done on the battery. (d) Initial electrostatic field energy Ui = (1/2) CV₁² Final Electrostatic field energy Uf = (1/2) CV₂² ∴ Decrease in Electrostatic Field energy = (1/2) CV₁²– (1/2) CV₂² = (1/2)C(V₁² – V₂²) = (1/2) × 100(576 –144) = 21600J ∴ Energy = 21600j = 21.6mJ (e)After reconnection C = 100μc, V = 12v ∴ The energy appeared = (1/2)CV₂ = (1/2) × 100 × 144 = 7200J = 7.2mJ This amount of energy is developed as heat when the charge flow through the capacitor.

A capacitor having a capacitance of 100μF is charged to a potential difference of 24V. The charging battery is disconnected and the capacitor is connected to another battery of emf 12V with the positive plate of the capacitor joined with the positive terminal of the battery, (a) Find the charges on the capacitor before and after the reconnection. (b) Find the charge flown through the 12V battery, (c) Is work done by the battery or is it done on the battery? Find its magnitude, (d) Find the decrease in electrostatic field energy, (e) Find the heat developed during the flow of charge after reconnection.

Answer»

(a) Before reconnection

C = 100μf

V = 24V

q = CV = 2400μc (Before reconnection)

After connection

When C = 100μf

V = 12V

q = CV = 1200μc (After connection)

(b) C = 100, V = 12V

∴ q = CV = 1200v

W = vq = 12 × 1200 = 14400J = 14.4mJ The work done on the battery.

(d) Initial electrostatic field energy Ui = (1/2) CV₁²

Final Electrostatic field energy Uf = (1/2) CV₂²

∴ Decrease in Electrostatic

Field energy = (1/2) CV₁²– (1/2) CV₂²

= (1/2)C(V₁² – V₂²) = (1/2) × 100(576 –144) = 21600J

∴ Energy = 21600j = 21.6mJ

(e)After reconnection

C = 100μc,

V = 12v

∴ The energy appeared = (1/2)CV₂ = (1/2) × 100 × 144 = 7200J = 7.2mJ

This amount of energy is developed as heat when the charge flow through the capacitor.