NaCl when placed in a uniform electric field `20VM^-1`, both `Na^+` and `Cl^-` ions experience a force (average distance between `Na^+` and `Cl^-` is 1.3A). Br Arrive an expression for torque experienced by the dipole.

NaCl when placed in a uniform electric field 20Vm^-1 , both Na^+ and Cl^- ions experience a force (average distance between Na^+ and Cl^- is 1.3A). Br Calculate the maximum torque experience by the NaCl molecule in the electric field.

NaCl when placed in a uniform electric field 20VM^-1 , both Na^+ and Cl^- ions experience a force (average distance between Na^+ and Cl^- is 1.3A). Br In what way the NaCl will orient in the electric field.

When a current carrying conductor is placed in a magnetic field it experiences a force. : Arrive at the expression for the force experienced by the conductor.

In a NaCl molecule there is an attractive force between Na^+ ion and Cl^- ion br Which law help us to find this attractive force? State the law.

A dipole of dipole moment 10^(-7) Cm in the negative z-direction is placed in an electric field along the positive z-direction. The magnitude of electric field increases uniformly along the positive z-direction, at the rate of 10^(5) NC^(-1) per meter. The force experienced by the dipole is :

In a NaCl molecule there is an attractive force between Na^+ ion and Cl^- ion br Why NaCl molecule is easily soluble in water?

An electric dipole placed in an electric field experiences a torque. When a dipole is placed in a uniform electric field the torque acting on it is found to be 0.707 times the maximum torque. Calculate the angle between the Intensity of electric fied and electric dipole moment and draw the orientation of the dipole in the electric field.

An electric dipole is placed in a uniform electric field of Intensity E as shown in the figure. Copy the diagram, mark the forces and derive an expression for torque.

An electric dipole has a fixed dipole moment P, which makes angle theta with respect to X-axis. When subjected to an electric field E_(1) = E hat(i) , it experiences a torque tau_(1) . When subjected to another electric field E_(2) = sqrt(3) E_(1) hat(j) , it experiences torque tau_(2) = - tau_(1) . Then angle theta is