In terms of potential difference V, electric current I, permitivity `epsi_(0)`, permeability `mu_(0)` and speed of light c, the dimensionally correct equations (s) is (are) :

In terms of potential difference C , electric current I , permittivity epsilon_(0) , permeability mu_(0) and speed of light c , the dimensionally correct equation (s) is (are)

The curves (a) , (b) , ( c ) and (d) show the variation between the applied potential difference (V) and the photoelectric current (i) , at two different intensities of light (I_(1) gt I_(2)) . In which figure is the correct variation shown ?

Stopping potential depends on planks constant (h), current (I), universal gravitational constant (G) and speed of light (C) choose the correct option for the dimension of stopping potential (V).

What is the potential difference V_(B)-V_(A) when the current i is 5A and is decreasing at a rate of 10^(3) A /s

The optical properties of a medium are governed by the relative permittivity (epsi_(r)) and relative permeability (mu_(r)) . The refractive index is defined as sqrt(mu_(r)epsi_(r))=n . For ordinary material, epsi_(r) gt 0 and mu_(r) gt 0 and the positive sign is taken for the squre root. In 1964, a Russian scientist V. Veselago postualted the existance of material with epsi_(r) lt 0 and mu_(r) lt 0 . Since, then such metamaterial have been produced in the laboratories and their optical properties studied. For such materials n= - sqrt(mu_(r) epsi_(r)) . As light enters a medium of such refractive index the phases travel away from the direction of propagation. (i) According to the description above show that if rays of light enter such a medium from air ( refractive index =1) at an angle theta in 2nd quadrant, then the refracted beam is in the 3rd quadrant. (ii) Prove that Snell's law holds for such a medium.

Using method of dimensions, establish the relation among the given quantities. (a) The potential difference V across a conductor depends on current i flowing in it and resistance of conductor R . (b) The speed of light c can be expressed in terms of free space mu_(0) . The energy U stored in an inductor is function of inductance L and current i flowing through it. (d) The time constant tau to R - C circuit can be expressed in terms of resistance R and capacitance. C . Dimensional formulae: V : ML^(2) T^(-3) A^(-1). R: ML^(2) T^(-3) A^(-2) , in_(0) : M^(-1) L^(-3) T^(4) A^(2), mu_(0) : MLT^(-2) A^(2) , L : ML^(2) T^(-2) A^(-2), C : M^(-1) L^(-2) T^(4) A^(2)

In an electric circuit, potential difference across a lamp is 20 V and current through the lamp is 0.5A. The resistance of the lamp is

If 220 V potential difference is appled across an electric bulb, a current of 0.45 A flows in the bulb. What must be the power of the bulb ?