If `V_1 and V_2` are stopping potentials for incident photons of wavelengths `lambda_1 andlambda_2` for same cathode material, then Planck's constant is given by [e = charge on electron, c = speed of light]

The maximum velocity of an electron emitted by light of wavelength lambda incident on the surface of a metal of work function phi , is Where h = Planck's constant , m = mass of electron and c = speed of light.

The stopping potential for photoelectrons from a metal surface is V_(1) when monochromatic light of frequency upsilon_(1) is incident on it. The stopping potential becomes V_(2) when monochromatic light of another frequency is incident on the same metal surface. If h be the Planck’s constant and e be the charge of an electron, then the frequency of light in the second case is:

When photon of wavelength lambda_(1) are incident on an isolated shere supended by an insulated , the corresponding stopping potential is found to be V . When photon of wavelength lambda_(2) are used , the orresponding stopping potential was thrice the above value. If light of wavelength lambda_(3) is used , carculate the stopping potential for this case.

For photoelectric effect with incident photon wavelength lamda , the stopping potential is V_0 Select the correct graph.

When light of wavelength lambda is incident on photosensitive surface, the stopping potential is V. When light of wavelength 3lambda is incident on same surface, the stopping potential is V/6 Thereshould wave length for the surface is

The energy of a photon of wavelength lambda is [ h = Planck's constant, c = speed of light in vacuum ]

In a photoelectric experiment using a sodium surface, you find a stopping potential of 1.85 V for a wavelength of 300 nm and a stopping potential of 0.820 V for a wavelength of 400 nm. From these data find (a) a value for the Planck constant, (b) the work function Phi for sodium, and (c) the cutoff wavelength lambda_(0) for sodium.

When light of wavelength lambda is incident on a metal surface, stopping potential is found to be x. When light of wavelength n lambda is incident on the same metal surface, stopping potential is found to be (x)/(n+1) . Find the threshold wavelength of the metal.

When a photosensitive surface is illuminated with light of wavelength lambda , the stopping potential is V_(0) . But when light of wavelength 2lambda is incident on the same surface, the stopping potential is (V_(0))/(4) . What is the threshold wavelength for the surface ?