Radiation of wavelength `lambda` in indent on a photocell . The fastest emitted electron has speed `v` if the wavelength is changed to `(3 lambda)/(4)` , then speed of the fastest emitted electron will be

In a photomissive cell with executing wavelength lamda//2 , work function phi , the fastest moving electron has acquired speed as v. If the executing wavelength is changed to (5lamda)/4 , the speed of the fastest emitted electron will be

In a photoelectric experiment, with light of wavelength lambda , the fastest election has speed v. If the exciting wavelength is changed to (3lambda)/4 , the speed of the fastest emitted electron will become

In a photoelectric experiment, with light of wavelength lamda , the fastest electron has speed v. If the exciting wavelength is changed to 5lamda/4 , the speed of the fastest emitted electron will become

In a photoemissive cell, with exciting wavelength lambda , the faster electron has speed v. If the exciting wavelength is changed to 3lambda//4 , the speed of the fastest electron will be

In a photo-emissive cell, with exciting wavelength lambda , the maximum kinetic energy of electron is K. If the exciting wavelength is changed to ( 3 lambda)/( 4) the kinetic energy of the fastest emitted electron will be :

If light of wavelength lambda_(1) is allowed to fall on a metal , then kinetic energy of photoelectrons emitted is E_(1) . If wavelength of light changes to lambda_(2) then kinetic energy of electrons changes to E_(2) . Then work function of the metal is

A monochromatic light of wavelength lambda is incident on an isolated metalic sphere of radius a . The threshold wavelength is lambda_(0) which is larger then lambda . Find the number of photoelectrons emitted before the emission of photo electrons stops.

When a metallic surface is illuminated with radiation of wavelength lambda , the stopping potential is V . If the same surface is illuminated with radiation of wavelength 2 lambda , the stopping potential is (V)/(4) . The threshold wavelength surface is :