The dimension of stooping potential `V_(0)` in photoelectric effect In units of Planck's constant 'h', speed of light 'c' and Gravitational constant 'G' and ampere A is:

The dimensional formula for Planck's constant and gravitational constant G respectively are :-

The dimension of the quantity 1/epsilon_0 e^2/(hc) is (e charge of electron,h Planck's constant and c=velocity of light)

The ratio of S.I unit of the C.G.S unit of gravitational constant 'G' is-

h d G has the dimensions of (h = height , d = density , G = Gravitational constant)

The dimensions of length are expressed as G^(x)c^(y)h^(z) , where G, c and h are the universal gravitational constant, speed of light and Planck's constant respectively, then :

Expression for time in terms of G (universal gravitational constant), h (Planck constant) and c (speed of light) is proportional to:

The dimensions of Stefan-Boltzman constant sigma can be written in terms of Plank's constant h. Boltzmann constant k_(B) and the speed of light c as sigma = h^(alpha) K_(B)^(b) c^(Y) . Here

The emission of electrons from a metal surface exposed rto light radaition of appropriate wavelength is called photoelectric effect .The emmited electron are called photo=-weklectron work function of threshold energy may be defined as the minimum amount of energy required to ejected electron from a most surface .According to Einstein Maximum kinetic energy of ejected electron = Absorbed energy - Work function (1)/(2) mv_(max)^(2) = h(v) - h(v_(n)) = hv [(1)/(lambda) - (1)/(lambda_(n))] Where v_(n) and lambda_(0) are thereshold frequency and threshold wavelength respectively Sopping potential : it is the miximum potential at which the photoelectric current becomes zero if V_(0) is the stopping potential eV_(0) = h(v- v_(0)) In the photoelectric currect effect the shape of strainght line graph between stopping potential (V_(0)) and frequency of incident light (V) gves

The stopping potential V for photoelectric emission from a metal surface is plotted along Y - axis and frequency v of incident light along X - axis . A straight line is obtained as shown . Planck's constant is given by

The stopping potential V for photoelectric emission from a metal surface is plotted along Y - axis and frequency v of incident light along X - axis . A straight line is obtained as shown . Planck's constant is given by