Write the dimensions of `E/B`. Here, `E` is the electric field and B the magnetic field.

The dimensions of the quantity vecE xx vecB , where vecE represents the electric field and vecB the magnetic field may be given as :-

Electric field induced by changing magnetic fields are

At time t_(1) , an electron is sent along the positive direction of x-axis through both an electric field and a magnetic field, with directed parallel to the y-axis Graph gives the y-component E_(max) of the net force on the electron due to the two fields, as a function of th eelectron's speed V at time t_(1) . Assuming B_(x) = 0 , find magnitude of electric field in mN//C and find z component of magnetic field also (Use e = 1.6 xx 10^(-19) C )

A He^(2+) at rest experiences an electromagnetic force. Then (where E is electric field and is B magnetic field)

A charge particle travels along a straight line with a speed v in region where both electric field E and magnetic field b are present.It follows that

Find the dimensions of a. electric field E, magnetic field B and magnetic permeability mu_0 . The relavant equations are F=qE, FqvB, and B=(mu_0I)/(2pi alpha), where F is force q is charge, nu is speed I is current, and alpha is distance.

The dimension of (B^(2))/(2mu_(0)), where B is magnetic field and mu_(0) is the magnetic permeability of vacuum, is :

An electron enters a region of space in which there exists an electric field 'E' and magnetic field 'B'. If the electron continues to move in the same direction with same velocity as before, the NOT possible case among the following is

Can a photon be deflected by an electric field ? By a magnetic field ?

When light propagates in vacuum there is an electric field and a magnetic field. These fields are