The Lyman series occurs for the excited electron at n=1 energy level and the Blamer series occurs for the excited electron at n=2 energy level.

Consider the formula for the charge to mass ratio in the electron and the proton as follows:

\[\begin{array}{c}\frac{{{q_e}}}{{{m_e}}} =  - 1.76 \times {10^{11}}\;\frac{{\rm{C}}}{{{\rm{kg}}}}\\\frac{{{q_p}}}{{{m_p}}} = 9.57 \times {10^7}\;\frac{{\rm{C}}}{{{\rm{kg}}}}\end{array}\]

Here, \[{m_e} = 9.11 \times {10^{ - 31}}\;{\rm{kg}}\] is the mass of the electron and \[{m_p} = 1.67 \times {10^{ - 27}}\;{\rm{kg}}\] is the mass of the proton.

Consider the formula for the Bohr's theory of hydrogen atom.

\[\frac{1}{\lambda } = R\left( {\frac{1}{{n_f^2}} - \frac{1}{{n_i^2}}} \right)\]

Here, wavelength of the emitted electromagnetic radiation is \[\lambda \], and the Rydberg constant is \[R = 1.097 \times {10^7}\;{{\rm{m}}^{ - 1}}\].

For Balmer series,\[{n_f} = 2\]

Case 1: For \[{n_i} = 3\]

Substitute \[R = 1.097 \times {10^7}{m^{ - 1}},{n_f} = 2\]and \[{n_i} = 3\]

The Wavelength is calculated as:

\[\begin{array}{c}\frac{1}{\lambda } = \left( {1.097 \times {{10}^7}\;{{\rm{m}}^{ - 1}}} \right)\left( {\frac{1}{{{2^2}}} - \frac{1}{{{3^2}}}} \right)\\\frac{1}{\lambda } = \left( {1.097 \times {{10}^7}\;{{\rm{m}}^{ - 1}}} \right)\left( {\frac{1}{4} - \frac{1}{9}} \right)\\\frac{1}{\lambda } = 1.524 \times {10^6}\;{{\rm{m}}^{ - 1}}\\\lambda  = 656.53\;{\rm{nm}}\end{array}\]

Also the known value is656.5nm

Thus, percentage difference is calculated as:

\[\frac{{656.5\;{\rm{nm}} - 656.3\;{\rm{nm}}}}{{656.5\;{\rm{nm}}}} \times 100 = 0.030\% \]

Case 2: For \[{n_i} = 4\]

Substitute\[R = 1.097 \times {10^7}\;{{\rm{m}}^{ - 1}},\;{n_f} = 2,\;{n_i} = 4\].

The Wavelength is calculated as:

\[\begin{array}{c}\frac{1}{\lambda } = \left( {1.097 \times {{10}^{7\;}}{{\rm{m}}^{ - 1}}} \right)\left( {\frac{1}{{{2^2}}} - \frac{1}{{{4^2}}}} \right)\\\frac{1}{\lambda } = \left( {1.097 \times {{10}^7}\;{{\rm{m}}^{ - 1}}} \right)\left( {\frac{1}{4} - \frac{1}{{16}}} \right)\\\frac{1}{\lambda } = 2.057 \times {10^6}\;{{\rm{m}}^{ - 1}}\\\lambda  = 486.17\;\;{\rm{nm}}\end{array}\]

Also, the known value is486.3nm.

Thus, percentage difference is determine as:

\[\frac{{486.3\;{\rm{nm}} - 486.14\;{\rm{nm}}}}{{486.3\;{\rm{nm}}}} \times 100 = 0.032\% \]

Case 3: For \[{n_i} = 5\]

Substitute\[R = 1.097 \times {10^7}\;{{\rm{m}}^{ - 1}},\;{n_f} = 2,\;{n_i} = 5\]

The Wavelength is calculated as

\[\begin{array}{c}\frac{1}{\lambda } = \left( {1.097 \times {{10}^7}\;{{\rm{m}}^{ - 1}}} \right)\left( {\frac{1}{{{2^2}}} - \frac{1}{{{5^2}}}} \right)\\\frac{1}{\lambda } = \left( {1.097 \times {{10}^7}\;{{\rm{m}}^{ - 1}}} \right)\left( {\frac{1}{4} - \frac{1}{{25}}} \right)\\\lambda  = 434\;{\rm{nm}}\end{array}\]

Also, the known value is434.2nm.

Thus, percentage differenceis calculated as:

\[\frac{{434.2\;{\rm{nm}} - 434\;{\rm{nm}}}}{{434.2\;{\rm{nm}}}} \times 100 = 0.046\% \]

Case 4: For\[{n_i} = 6\]

Substitute\[R = 1.097 \times {10^7}\;{{\rm{m}}^{ - 1}},\;{n_f} = 2,\;{n_i} = 6\]

The Wavelength is calculated as

\[\begin{array}{c}\frac{1}{\lambda } = \left( {1.097 \times {{10}^7}\;{{\rm{m}}^{ - 1}}} \right)\left( {\frac{1}{{{2^2}}} - \frac{1}{{{6^2}}}} \right)\\\frac{1}{\lambda } = \left( {1.097 \times {{10}^7}\;{{\rm{m}}^{ - 1}}} \right)\left( {\frac{1}{4} - \frac{1}{{36}}} \right)\\\lambda  = 410.2\;{\rm{nm}}\end{array}\]

Also, the known value is 410.3

Thus, percentage differenceis determined as:

\[\frac{{410.3\;{\rm{nm}} - 410.2\;{\rm{nm}}}}{{410.3\;{\rm{nm}}}} \times 100 = 0.024\% \]

Hence, the average percentage difference found is 0.025 %. The phenomenon is amazing as it shows the error between the actual value and the wavelength of the calculated value of the energy level is also approximately equal to zero.