In a photoelectric experiment, the wavelenght of the light incident on a menatl is changed from 300 nm to 400nm. The decreases in the stopping potential is close to : `((hc)/(e) = 1240 nm -V)`

In a photoelectric experiment, the wavelength of the light incident on a metal is changed from 300 nm to 400 nm. Choose the closest value of change in the stopping potential from given options ((hc)/(e)=1240 nm.V)

In a photoelectric experiment, the wavelength of the light incident on a metal is changed from 300 nm to 400 nm. Choose the closest value of change in the stopping potential from given options ((hc)/(e)=1240 nm.V)

In a photoelectric experiment the wavelength of incident light changes from 4000 Å to 2000 Å. The change in stopping potential is

In a photoelectric experiment, the wavelength of the incident light is decreased from 6000A to 4000A . While the intensity of radiations remains the same,

If in a photoelectric cell , the wavelength of incident light is changed from 4000 Å to 3000 Å then change in stopping potential will be

In a photoelectric cell, the wavelength of incident light is chaged from 4000A to 3600A . The change in stopping potential will be

Suppose the wavelength of the incident light is increased from 3000 Å to 3040Å . Find the corresponding change in the stopping potential. [Take the product hc=12.4xx10^(-7)eVm) ]

If wavelength of incident radiation changes from 500 nm to 200 nm then the maximum kinetic energy increases to 3 times. Find work function ?

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.

In a photoelectric experiment, the graph of frequency v of incident light (in Hz) and stopping potential V (in V) is as shown in the figure. Planck's constant is (e is the elementary charge)