the excitation energy of lyman last lines is

The excitation energy of a hydrogen -like ion in its first excited state is 40.8 eV Find the energy needed to remain the electron from the ion

The excitation energy of a hydrogen-like ion in its first excited state is 40.8 eV Find the energy needed to remove the electron from the ion

Find the excitation energy of n = 3 level of He atom

If the first excitation energy of a hydrogen - like atom is 27.3 eV , then ionization energy of this atom will be

Excitations energy of hydrogen atom is 13.6 eV match the following

Given that ionization energy of hydrogen atom is 13.6 eV, calculate the wavelength of first line of the Lyman series.

A photoelectric plate is initially exposed to a spectrum of hydrogen gas excited to second energy level. Late when the same photoelectric plate is exposed to a spectrum of some unknown hydrogen like gas, excited to second energy level. It is found that the de-Broglie wavelength of the photoelectrons now ejected has increased sqrt(6.1) times. For this new gas difference of energies of first Lyman line and Balmer series limit is found to be two times the ionization energy of the hydrogen atom is ground state. Detect the atom and determine the work function of the photoelectric plate.

The total energy of an electron in the first excited state of hydrogen is about -3.4 eV . Its kinetic energy in this state is:

the photon radiated from hydrogen corresponding to the second line of Lyman series is absorbed by a hydrogen like atom X in the second excited state. Then, the hydrogen-like atom X makes a transition of nth orbit.

The photon radiated from hydrogen corresponding to the second line of Lyman series is absorbed by a hydrogen like atom X in the second excited state. Then, the hydrogen-like atom X makes a transition of nth orbit.