The `IP_(1) `of H is `13.6 eV` it is expoxed to electromagnetic waves of 1028A^@ and gives out induced radiation .Find the wavelength of these induced radiation

A hydrogen like ion He^(o+) (Z = 2) is exposed to electromagnetic waves of 256.4 Å The excited electron gives out induced radiation .Find the wavelength of the induced radiation when the electron de-excites back to the ground state (R = 109677 cm^(-1))

H-atom is exposed to electromagnetic radiation of lambda=1025.6 Å and excited atom gives out induced radiation. What is the minimum wavelength of the induced radiation? (a) 102.6 nm (b) 12.09 nm (c) 121.6 nm (d) 810.8 nm

A hypothetical electromagnetic wave is shown in figure. Find out the wavelength of the radiation.

The frequency of a radiation belonging to radio waves is 3 xx 10^(7)Hz . Find the wave number and wavelength of the radiation.

A gas of hydrogen - like atoms can absorb radiations of 698 eV . Consequently , the atoms emit radiation of only three different wavelengths . All the wavelengthsare equal to or smaller than that of the absorbed photon. a Determine the initial state of the gas atoms. b Identify the gas atoms c Find the minimum wavelength of the emitted radiation , d Find the ionization energy and the respective wavelength for the gas atoms.

The electrical conductivity of a semiconductor increases when electromagnetic radiation of wavelength shorter than 2480 nm is incident on it. Find the band gap of the semiconductor.

A single electron orbits around a stationary nucleus of charge +Ze , where Z is a constant and e is the electronic charge. It requires 47.2 eV to excited the electron from the second Bohr orbit to the third Bohr orbit. Find (i) the value of Z, (ii) the energy required to excite the electron from the third to the fourth Bohr orbit and (iii) the wavelength of the electromagnetic radiation radiation to remove the electron from the first Bohr orbit to infinity.

The ionization enegry of the electron in the hydrogen atom in its ground state is 13.6 ev . The atoms are excited to higher energy levels to emit radiations of 6 wavelengths. Maximum wavelength of emitted radiation corresponds to the transition between

The ionization enegry of the electron in the hydrogen atom in its ground state is 13.6 ev . The atoms are excited to higher energy levels to emit radiations of 6 wavelengths. Maximum wavelength of emitted radiation corresponds to the transition between

The stopping potential for the photoelectrons emitted from a metal surface of work function 1.7 eV is 10.4 V. Find the wavelength of the radiation used. Also, identify the energy levels in hydrogen atom, which will emit this wavelength.