A photodiode activeness when photon of wavelength 612 nm incident on it. Then the depletion layer voltage of photodiode will be (given: hc = 1224 ev-nm)

The energy of a photon in eV of wavelength lambda nm 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

A P-N junction becomes active as photons of wavelength, lambda=400 nm falls on it. Find the energy band gap?

The electrical conductivity of a semiconductor increases wen electromagnetic radiations of wavelength shorter than 2480 nm is incident on it. The band gap (in eV) for the semiconductor is [ hc = 1242 e V n m ]

Electrons of 0.5 eV energy are emitted from a metal surface when photons of wavelength 3000 Å are incident. The energy of electrons, when photons of 2000 Å are incident will be

The electrical conductivity of a semiconductor increases when electromagnatic radiation of wavelength shorter than 2480 nm is incident on it. The band gap (in eV) for the semiconductor is [hc=1242 eV nm]

The electrical conductivity of a semiconductor increases when electromagnetic radiation of wavelength shorter than 1240 nm is incident on it. The forbidden band energy for the semi conductor is (in eV).

Conductivity of a semiconuctor increases when a radiation of wavelength is less than 2480 nm is incident on it. The forbidden gap is

If light of wavelength 412.5 nm is incident on each of the metals given below, which one will show photoelectric emission and why? .