The peak emission from a black body at a...

The peak emission from a black body at a certain temprature occurs at a wavelength of `9000 Å`. On increase its temperature , the total radiation emmited is increased its `81` times. At the intial temperature when the peak radiation from the black body is incident on a metal surface , it does not cause any photoemission from the surface . After the increase of temperature, the peak from the black body caused photoemission. To bring these photoelectrons to rest , a potential equivalent to the excitation energy between `n = 2 and n = 3` bohr levels of hydrogen atoms is required. Find the work function of the metal.

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Peak emission from a black body at a certain temperature occures at a wavelength lambda. On increasing its temperature , total radiation emitted is increasing 16 times . At the initial temperature when peak radiation from the black body is incident on a metal surface , it does not cause photoemission from surface . After the increasing the peak radiation from black body caused photoemission. to bring these photoelectrons to rest, a potential equivalent to the excitation energy between n=2 to n=3 Bohr levels of hydrogen atom is required. if eork function of metal is 2.24eV , then value of lambda is [hc=12400eV-Å]

From a black body, radiation is not :

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