Dimensions of `epsi_(0) (dphi_(E))/(dt)` are same as that of

If E = energy , G = gravitational constant, I =impulse and M =mass, then dimensions of (GIM^(2))/(E^(2) are same as that of

The dimensions of velocity gradient are the same as that of

Write the dimensions of (dphi_B)/(dt) .

The dimension of 1/(sqrt(mu_(0)epsilon_(0))) are same as

The dimensions of (1)/(epsilon_(0))(e^(2))/(hc) are

The maxwell’s equation : oint vec(B).vec(dl) = mu_(0) (i+varepsilon_(0).(dphi_(E))/dt) is a statement of -

A plane EM wave travelling in vacuum along z-direction is given by E=E_(0) " sin "(kz- omegat) hati " and " B =B_(0) " sin " (kz- omegat) hatj (i) Evaluate intE. dl over the rectangular loop 1234 shown in figure. (ii) Evaluate int B.ds over the surface bounded by loop 1234. (iii) Use equation int E.dl = (-dphi_(B))/(dt) to prove (E_(0))/(B_(0)) =c. (iv) By using similar proces and the equation int B.dl =mu_(0) I+ epsilon_(0) (dphi_(E))/(dt), prove that c (1)/(sqrt(mu_(0) epsilon_(0))

Consider a parallel plate capacitor, of capacitance C, plate area A and plate separation d. It is being charged by using a battery. The quantity epsilon_(0)(d phi_(E))/(dt) has the dimensions of [ epsilon_(0) =permittivity of free space, phi_(E) is the electric flux, dt = time]