Light of energy 2.0 eV falls on a metal of work function 1.4 eV . The stopping potential is

When photon of energy 3.8 eV falls on metallic suface of work function 2.8 eV , then the kinetic energy of emitted electrons are

Radiation from a hydrogen discharge tube ( energy of photons le 13.6 eV ) goes through a fliter which transmits only waves of wavelength greater than 4400Å and is incident on a metal of work function 2.0 eV . If stopping potential is nxx10^(-2) volts. Find the value of 'n'

Light of wavelenght 5000 Å fall on a metal surface of work function 1.9 eV Find a. The energy of photon

Monochromatic light of wavelength 198 nm is incident on the surface of a metal, whose work function is 2.5 eV. Calculate the stopping potential.

The maximum kinetic energy of photoelectrons emitted from a surface when photons of energy 6 eV fall on it is 4 eV . The stopping potential , in volt is

Aphoton of energy 4.5 eV strikes on a metal surface of work function 3.0 eV. If uncertainty in position is (25)/(4pi)Å, find the uncertainty in measurment of deBroglie wavelength (inÅ ).

Light of wavelength 2000 Å falls on a metallic surface whose work function is 4.21 eV. Calculate the stopping potential

A photon of energy 4 eV is incident on a metal surface whose work function is 2 eV . The minimum reverse potential to be applied for stopping the emission of electrons is

Photons of energy 6 eV are incident on a metal surface whose work function is 4 eV . The minimum kinetic energy of the emitted photo - electrons will be

Electromagnetic radiations of wavelength 2000Å are incident on a metal surface which has a work function 5.01 eV The stopping potential for the given setup is