Question

What is the wavelength of light emitted when the electron in a hydrogen atom undergoes transition from an energy level with n = 4 to an energy level with n = 2?

Answer 1

The n_i = 4 to n_f = 2 transition will give rise to a spectral line of the Balmer series. The energy involved in the transition is given by the relation,
\(E = 2.18 × 10^{-18} [\frac {1}{n_i^2}- \frac {1}{n_f^2}]\)
Substituting the values in the given expression of E:
\(E = 2.18 × 10^{-18} [\frac {1}{4^2}- \frac {1}{2^2}]\)

\(E = 2.18 × 10^{-18} [\frac {1-4}{16}]\)

\(E = 2.18 × 10^{-18} (\frac {-3}{16})\)

\(E = - (4.0875×10^{-19}\ J)\)
The negative sign indicates the energy of emission. 
Wavelength of light emitted \(λ = \frac {hc}{E}\)
Substituting the values in the given expression of λ:
\(λ = \frac {(6.626×10^{-34})(3×10^8)}{4.0875×10^{-19}}\)
\(λ = 4.8631×10^{-7} m\)
\(λ= 486.3×10^{-9} m\)
\(λ= 486\  nm\)