As per quantum theory the energy E of a photon is related to its frequency `nu` as E = h`nu` , where h`nu` = Planck's constant. Then the dimension of h would be

Photon is the quantum of radiation with energy E = h nu where nu is frequency and h is Planck's constant. The dimension of h is the same as that of

n number of photons of frequency f are emitted per second from a light source of power P (h = Planck's constant, c = speed of light). Then

The wavelength of a light is 0.01 Å . If h be the Planck's constant, then the momentum of the corresponding photon will be

The maximum energies of photoelectrons emitted by a metal are E_(1) and E_(2) when the incident radiation has frequencies f_(1) and f_(2) respectively. Show that Planck's constant h and the work function W_(0) of the metal are h = (E_(1) - E_(2))/(f_(1) - f_(2)), W_(0) = (E_(1) f_(2) - E_(2) f_(1))/(f_(1) - f_(2))

Find the temperature at which the average kinetic energy of a gas molecule will be equal to the energy of a photon to 6000 Angstrom radiation. Given,Boltzmann constant, k=1.38 times 10^-23 J.K^-1 Planck's constant, h=6.625 times 10^-34 J.s .

Einstein established the idea of photons on the basis of Planck's quantum theory. According to his idea, the light of frequency f or wavelength lamda is infact a stream of photons. The rest mass of each photon is zero and velocity is equal to the velocity of light (c) = 3 xx 10^(8) m.s^(-1) . Energy, E = hf, where h = Planck's constant = 6.625 xx 10^(-34)J.s . Each photon has a momentum p = (hf)/(c) , although its rest mass is zero. The number of photons increase when the intensity of incident light increases and vice-versa. On the other hand, according to de Broglie any stream of moving particles may be represented by progressive waves. The wavelength of the wave (de Broglie wavelength) is lamda = (h)/(p) , where p is the momentum of the particle. When a particle having charge e is accelerated with a potential difference of V, the kinetic energy gained by the particle is K= eV. Thus as the applied potential difference is increased, the kinetic energy of the particle and hence the momentum increase resulting in a decrease in the de Broglie wavelength. Given, charge of electron, e = 1.6 xx 10^(-19)C and mass = 9.1 xx 10^(-31) kg . The number of photons emitted per second from a light source of power 40 W and wavelength 5893 Å

Einstein established the idea of photons on the basis of Planck's quantum theory. According to his idea, the light of frequency f or wavelength lamda is infact a stream of photons. The rest mass of each photon is zero and velocity is equal to the velocity of light (c) = 3 xx 10^(8) m.s^(-1) . Energy, E = hf, where h = Planck's constant = 6.625 xx 10^(-34)J.s . Each photon has a momentum p = (hf)/(c) , although its rest mass is zero. The number of photons increase when the intensity of incident light increases and vice-versa. On the other hand, according to de Broglie any stream of moving particles may be represented by progressive waves. The wavelength of the wave (de Broglie wavelength) is lamda = (h)/(p) , where p is the momentum of the particle. When a particle having charge e is accelerated with a potential difference of V, the kinetic energy gained by the particle is K= eV. Thus as the applied potential difference is increased, the kinetic energy of the particle and hence the momentum increase resulting in a decrease in the de Broglie wavelength. Given, charge of electron, e = 1.6 xx 10^(-19)C and mass = 9.1 xx 10^(-31) kg . The number of photons emitted per second by a source of light of power 30 W is 10^(20) , the momentum of each photon (in kg.m.s^(-1) )