An electromagnetic wave is propagating along x-axis. At x = 1 m and t = 10 s, its electric vector `|vecE|=6V//m` then the magnitude of its magnetic vector is

An electronmagnetic wae propagating along x-axis then oscillating electric and magnetic field vectors are along

In a plane electromagnetic wave propagating in space has an electric field of amplitude 9 × 10^(3) V//m , then the amplitude of the magnetic field is

An electromagnetic wave propagating along north has its electric field vector upwards. Its magnetic field vector point towards

An electromagnetic wave is propagating in vacuum along z-axis, the electric field component is given by E_(x) = E_(0) sin (kz - omega t) , then magnetic component is

An electromagnetic wave is propagating in vacuum along z-axis, the electric field component is given by E_(x)=E_(0)sin (kz-omegat) . Then magnetic components is

A light wave is travelling along +y axis. At a particular point on a given time, electric field vector is along + x axis then the magnetic field vector is directed along:

An electromagnetic wave is propagating in vacuum along x-axis, which is produced by oscillating charge of frequency 3 xx 10^(10) Hz. The amplitude of magnetic field, 1 xx 10^(-7) T along z-axis find equation for oscillating electric field

A plane electromagnetic wave propagating in the x-direction has a wavelength of 6.0 mm. the electric field is in the y-direction and its maximum magnitude is 33 Vm^(-1) . Write suitable equations for the electric and magnetic fields as functions of x and t.

A plane electromagnetic wave propagating in the x-direction has a wavelength of 5.0 mm. The electric field is in the y-direction and its maximum magnitude is 30V (m^-1) . Write suitable equations for the electric and magnetic fields as a function of x and t.

A plane electromagnetic wave propagating along y-direction can have the following pair of electric field (vecE) and magnetic field (vecB) components.