Home
Class 12
PHYSICS
Find the energy stored in a capacitor of...

Find the energy stored in a capacitor of capacitance `100muF ` when it is charged to a potential difference of 20 V.

Text Solution

Verified by Experts

The energy stored in the capacitor is `
`U = (1)/(2) CV^2 = (1)/(2) (100 mu F) (20 V)^2 = 0.02 J`
`. The energy stored in a capacitor is electrostatic potential energy. When we pull the plates of a capacitor apart, we have to do work against the electrostatic attraction between the plates. In which region of space is the energy stored ? When we increase the separation between the plates from `
`d_1 to d_2`
`, an amount`
`(Q)^2/(2A epsilon_0) (d_2 - d_1)`
` of work is performed by us and The field due to the charges `
`Q_p, - Q_p`
` is directed oppositely and has magnitude `
`E_p =(sigma_p )/(epsilon_o) =(Q_p)/(Aepsilon_o)`
`. The resultant field is `
` E = E_0 - E_p`
` = (Q-Q_p)/(A epsilon_0)`
`. From equations (ii) and (iii), (Q - Q_p)/(epsilon_o A) = (Q)/(epsilon _o AK)`
` or, `
`Q - Q_p = (O)/(K)`
` or, `
`Q_p = Q (1 -(1)/(K)).
Doubtnut Promotions Banner Mobile Dark
|

Topper's Solved these Questions

  • CAPACITORS

    HC VERMA ENGLISH|Exercise worked out examples|23 Videos

  • CAPACITORS

    HC VERMA ENGLISH|Exercise Objective 1|12 Videos

  • BOHR'S MODEL AND PHYSICS OF THE ATOM

    HC VERMA ENGLISH|Exercise Short Answer|10 Videos

  • DISPERSION AND SPECTRA

    HC VERMA ENGLISH|Exercise Question for short Answer|6 Videos

Similar Questions

Explore conceptually related problems

The energy stored in 4 muF capacitors is

The energy stored in a capacitor of capacitance 100 muF is 50 J. Its potential difference is

Knowledge Check

  • A capacitor or capacitance C_(1) is charge to a potential V and then connected in parallel to an uncharged capacitor of capacitance C_(2) . The fianl potential difference across each capacitor will be

    A
    `(C_(1)V)/(C_(1)+C_(2))`
    B
    `(C_(2)V)/(C_(1)+C_(2))`
    C
    `1+(C_(2))/(C_(1))`
    D
    `1-(C_(2))/(C_(1))`

    • Similar Questions

    Explore conceptually related problems

    A capacitor of capacitance C_(1) is charged to a potential V_(1) while another capacitor of capacitance C_(2) is charged to a potential difference V_(2) . The capacitors are now disconnected from their respective charging batteries and connected in parallel to each other . (a) Find the total energy stored in the two capacitors before they are connected. (b) Find the total energy stored in the parallel combination of the two capacitors. (c ) Explain the reason for the difference of energy in parallel combination in comparison to the total energy before they are connected.

    A capacitor of capacitor of capacitance 2.0muF is charge to a potential diffrence of 12V It is then connected of uncharged capacitor of capacitance 4.0muF as shown in figure . Find (a ) the charge on each of the two capacitors after the connection, (b ) the electrostatic energy stored in each of the two capacitors.

    A 100 mu F capacitor is charged to a potential difference of 24 V . It is connected to an uncharged capacitor of capacitance 20 mu F What will be the new potential difference across the 100 mu F capacitor?

    Calculate the energy stored in the capacitor of capacitance 2muf . The voltmeter gives a reading of 15 V and the ammeter A reads 15mA .

    A radioactive sample decays with a mean life of 20ms. A capacitor of capacitance 100muF is charged to some potential and then the plates are connected to a resistance .R.. If the ratio of the charge on the capacitance to the activity of radioactive sample remains constant in time is R=100(x)Omega , then x=

    Three capacitors having capacitances of 8.4 muF, 8.4 muF and 4.2 muF are connected in series across a 36 potential difference. (a) What is the charge on 4.2muF capacitor? (b) What is the total energy stored in all three capacitors? (c) The capacitors are disconnected from the potential difference without allowing them to discharge. They are then reconnected in parallel with each other, with the positively charged plates connected together. What is the voltage across each capacitor in the parallel combination? (d) What is the total energy now stored in the capacitors?

    In the circuit shown in figure, the charge stored on a capacitor of capacitance 3muF is

    Home
    Profile