Home
Class 11
PHYSICS
Prove that the frequency of oscillation ...

Prove that the frequency of oscillation of an electric dipole of moment p and rotational inertia `I` for small amplitudes about its equilibrium position in a uniform electric field strength E is `1/(2pi) sqrt(((pE)/I))`

Text Solution

AI Generated Solution

To prove that the frequency of oscillation of an electric dipole of moment \( p \) and rotational inertia \( I \) for small amplitudes about its equilibrium position in a uniform electric field strength \( E \) is given by \[ f = \frac{1}{2\pi} \sqrt{\frac{pE}{I}}, \] we can follow these steps: ...
Promotional Banner

Topper's Solved these Questions

  • MISCELLANEOUS

    ALLEN|Exercise Part -II Example Some worked out Examples|1 Videos

  • MISCELLANEOUS

    ALLEN|Exercise Exercise-01|87 Videos

  • MISCELLANEOUS

    ALLEN|Exercise Question|1 Videos

  • KINEMATICS (MOTION ALONG A STRAIGHT LINE AND MOTION IN A PLANE)

    ALLEN|Exercise BEGINNER S BOX-7|8 Videos

  • PHYSICAL WORLD, UNITS AND DIMENSIONS & ERRORS IN MEASUREMENT

    ALLEN|Exercise EXERCISE-IV|8 Videos

Similar Questions

Explore conceptually related problems

The frequency of oscillation of an electric dipole moment having dipole moment p and rotational inertia l, oscillating in a uniform electric field E is given

The work in rotating electric dipole of dipole moment p in an electric field E through an angle theta from the direction of electric field, is:

An electric dipole of dipole moment p is placed in a uniform external electric field E. Then, the

(i) Derive the expression for electric field at a point on the equatorial line of an electric dipole. (ii) Depiet the orientation of the dipole in (i) stable, (ii) unstable equilibrium in a uniform electric field.

A small electric dipole is placed at origin with its dipole moment directed along positive x-axis .The direction of electric field at point (2,2sqrt(2),0)

An electric dipole moment vec P = ( 2. 0 hat I + 3 . 0 hat j) mu C m is placed in a uniform electric field vec E = (3 hat I + 2 . 0hat k ) xx 10^5 N C^(-1) .

A dipole consists of two particles one with charg +1 mu C and mass 1kg and the other with charge 1 mu C and mass 2kg separated by a distance of 3m. For small oscillations about its equilibrium position, the angular frequency when, placed in a uniform electric field of 20k V/m is ____

An electric dipole is situated in an electric field of uniform intensity E whose dipole moment is p and moment of inertia is I . If the dipole is displaced slightly from the equilibrium position, then the angular frequency of its oscilliations is

An electric dipole of dipole moment vec P is lying along uniform electric filed bar E . The work done in rotating the dipole by 37° is

Obtain the expression for the torque vec(tau) experienced by an electric dipole of dipole moment vec(p) in a uniform electric field , vec(E )

ALLEN-MISCELLANEOUS-Part -II Example
  1. Calculate force on a dipole in the surrounding of a long charged wire ...

    Text Solution

    |

  2. A short electric dipole is situated at the origin of coordinate axis w...

    Text Solution

    |

  3. Prove that the frequency of oscillation of an electric dipole of momen...

    Text Solution

    |

  4. Brass has a tensile strength 3.5xx10^(8) N//m^(2). What charge density...

    Text Solution

    |

  5. Prove that if an isolated (isolated means no charges are near the shee...

    Text Solution

    |

  6. If an isolated infinite plate contains a charge Q1 on one of its surfa...

    Text Solution

    |

  7. Three large conducting sheets placed parallel to each other at a finit...

    Text Solution

    |

  8. Two conducting plates A and B are placed parallel to each other. A is ...

    Text Solution

    |

  9. Figure shows three large metallic plates with charges -Q, 3Q and Q res...

    Text Solution

    |

  10. An isolated conducting sheet of area A and carrying a charge Q is plac...

    Text Solution

    |

  11. An uncharged conductor of inner radius R(1) and outer radius R(2) cons...

    Text Solution

    |

  12. An unchanged conductor of inner radius R(1) and outer radius R(2) cont...

    Text Solution

    |

  13. When the switch is closed find the charge flown through switch?

    Text Solution

    |

  14. The two conducting spherical shells are joined by a conducting wire wh...

    Text Solution

    |

  15. Find charge on each spherical shell after joining the inner most shell...

    Text Solution

    |

  16. Two conducting hollow spherical shells of radii R and 2R cerry charges...

    Text Solution

    |

  17. An isolated conducting sphere of charge Q and radius R is connected to...

    Text Solution

    |

  18. Two positrons (e+) and two protons (p) are kept on four corners of a s...

    Text Solution

    |

  19. Four charges are placed at the circumference of a dial clock as shown ...

    Text Solution

    |

  20. A small electric dipole is placed at origin with its dipole moment dir...

    Text Solution

    |