The wavelength `lambda_(e)` of an electron and `(lambda_(p)` of a photon of same energy E are related by

The ratio of wavelength of a photon and that of an electron of same energy E will be

The de-Broglie wavelength of an electron is same as the wavelength of a photon. The energy of a photon is ‘x’ times the K.E. of the electron, then ‘x’ is: (m-mass of electron, h-Planck’s constant, c - velocity of light)

The wavelengths of a photon, an electron and a uranium nucleus are same. Maximum energy will be of

The energy of a photon of wavelength lambda is

Momentum of a photon of wavelength lambda is :

Photon and electron are given same energy (10^(-20) J) . Wavelength associated with photon and electron are lambda_(ph) and lambda_(el) then correct statement will be

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 magnitude of the de-Broglie wavelength (lambda) of an electron (e) ,proton (p) ,neutron (n) and alpha particle (a) all having the same energy of Mev , in the increasing order will follow the sequence:

Ultraviolet light of wavelengths lambda_(1) and lambda_(2) when allowed to fall on hydrogen atoms in their ground state is found to liberate electrons with kinetic energy 1.8 eV and 4.0 eV respectively. Find the value of (lambda_(1))/(lambda_(2)) .

A dye absorbs a photon of wavelength lambda and re - emits the same energy into two phorons of wavelengths lambda_(1) and lambda_(2) respectively. The wavelength lambda is related with lambda_(1) and lambda_(2) as :