Suppose that means were available for stripping `28` electrons from `_29 Cu` in vapour of this metel.
a. Compute the first three energy level for the remaining electron.
b. Find the wavelength of the spectral line of the series for which `n_(1) = 1, n_(2) = 3,4`. What is the ionization potential for the last electron?

The energy levels of a hypotherical one electron atom are shown in figure Find the short wavelength limit of the series terminating at n = 2 .

Calculate the wavelength of the spectral line when an electron jumps from n=7 to n=4 level in an atom of hydrogen.

The wavelength of the spectral line when the electron is the hydrogen atom undergoes a transition from the energy level 4 to energy level 2 is.

The energy levels of a hypotherical one electron atom are shown in figure Find the wave number of the photon emitted for the transition n = 3 to n = 1

An electron in H -atoms jumps from some higher level to 3rd energy level.If three spectral lines are possible for the transition, find the initial position of electron.

A line in Lyman series of hydrogen atom has a wavelength of 1.03 xx 10^(-7)m . What is the initial energy level of the electron ?

For a certain hypothetical one electron atom, the wavelength (in Å) for the spectral lines for transitions originating at n=p and terminating at n=1 are given by lambda = (1500 p^2)/(p^2 - 1), where p = 2,3,4 (a)Find the wavelength of the least energetic and the most energetic photons in this series. (b) Construct an energy level diagram for this element showing the energies of the lowest three levels. (c ) What is the ionization potential fo this elelment?

When the electron in an excited hydrogen atom jumps from an energy level for which n=5 to level for which n=2 ,the spectral line is obeserved in which series of the hydrogen spectrum?

Brackett series of lines are producted when electrons excited t high energy level make transitions to the n = 4 level. a Determine the longest wavelength in this series. b Determine the wavelength that corresponds to the transition from n_(f) = 6 to n_(i) = 4 .

Electrons in a certain energy level n=n_(1) can emit 3 spectral lines. When they are in another energy level, n=n_(2) , they can emit 6 spectral lines. The orbital speed of the electrons in the two orbits are in the ratio