Light of wavelength `400nm` is incident continuously on a Cesium ball. (work function `1.9eV`). The maximum potential to which the ball will be charged is

Light of wavelength 3000Å is incident on a metal surface whose work function is 1 eV. The maximum velocity of emitted photoelectron will be

The radiation of wavelength 332 nm is incident on a metal of work function 1.70 eV. The value of the stopping potential will be

Light of wavelength 500 nm is incident on a metal with work function 2.28 eV . The de Broglie wavelength of the emitted electron is

Light of wavelength 250 nm falls on a photosensitive material with work function 3 eV. Find the stopping potential for this material.

Ultraviolet beam of wavelength 280 nm is incident on lithium surface of work function 2.5 eV. The maximum velocity of electron emitted from metal surface is

(a) Calculate KE of photoelectron emiited from sodium surface when light of wavelength 400nm is incident on it (Work function of sodium =2.28eV ). (b) Calculate maximum wavelength (threshold wavelength) that can cause emission of photoelectron from sodim surface.

Metal surface emits photoelectrons when light of wavelength 400 nm is incident on it. Calculate the work function of the metal if stopping potential is 0.5 V.

Light of wavelength 2000Å is incident on a metal surface of work function 3.0 eV. Find the minimum and maximum kinetic energy of the photoelectrons.

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

Light of wavelength 3500Å is incident on two metals A and B whose work functions are 3.2 eV and 1.9 eV respectively. Which metal will emit photoelectrons