Force `vec(F)` acting on a test charge `q_(0)` in a uniform electric field `vec(E)` is

Write an expression for potential energy of two charges q_(1) and q_(2) at vec(r_(1)) and vec(r_(2)) in a uniform electric field vec(E) .

A wooden block performs SHM on a frictionless surface with frequency, v_(0) . The block carries a charge +Q on its surface. If now a uniform electric field vec (E) is switched on as shwon in figure., then the SHM of the block will be

Direction of force acting on a current carrying conductor vec (L) in an external magnetic field vec(B) is

The torque tau acting on an electric dipole of dipole momtn vec(p) in an electric field vec( E ) is

Show that when an electric dipole is placed in a uniform electric field vec(E) , petential energy U is given by U = - vec(P) , vec(E)

An electric dipole of moment vec(P) is lying along a uniform electric field vec(E ) . The work done in rotating the dipole by 90^(@) is:

An electric dipole of dipole moment vec(P) is placed in a uniform electric field vec(E) such that vecP is perpendicular to vecE The work done to. turn the dipole through an angle of 180^@ is

The force acting on a charge q in both electric and magnetic field, stimulateneously is

A particle of mass m and charge q is moving in a region where uniform electric field underset(E)to and and uniform mag-netic field underset(B)to are present. It is given that underset(E)to/|vec(E)|=underset(B)to/|vec(B)|. At time t = 0, velocity of the particle is underset(V)to_(0) and underset(V)to_(0).underset(E)to=0. Write the velocity of the particle at time t.