Calculate the kinetic energy of the electron having wavelength 1 nm.

If the energy of the photon is (2 lambda_(p)mc)/(h) times the kinetic energy of the electron then show then the wavelength lambda of photon and the de Broglie wavelength of an electron have the same value (Where m, c and h have their usual meanings .)

The mass of photon having wavelength 1 nm is :

The wavelength lambda of a photon and the de-Broglie wavelength of an electron have the same value. Show that the energy of the photon is (2 lambda mc)/h times the kinetic energy of the electron, Where m,c and h have their usual meanings.

The de-Broglie wavelength of an electron is the same as that of a 50 keV X-ray photon. The ratio of the energy of the photon to the kinetic energy of the electron is ( the energy equivalent of electron mass of 0.5 MeV)

In a photo-emissive cell, with exciting wavelength lambda_1 , the maximum kinetic energy of electron is K. If the exciting wavelength is changed to lambda_2 , the maximum kinetic energy of electron is 2K then

Calculate the binding energy per mole when threshold wavelength of photon is 240nm

An electron, a neutron and an alpha particle have same kinetic energy and their de-Broglie wavelength are lambda_e, lambda_n and lambda_(alpha) respectively. Which statement is correct about their de-Broglie wavelengths?

An electron and a proton have same kinetic energy Ratio of their respective de-Broglie wavelength is about

Visible light has wavelengths in the range of 400 nm to 780nm. Calculate the range of energy of the photons of visible light.

If E_1, E_2 and E_3 represent respectively the kinetic energies of an electron, an alpha - particle and a proton each having same de-Broglie wavelength, then