Question: With the increase in quantum number the energy difference between consecutive energy levels A.rema...

Question

With the increase in quantum number the energy difference between consecutive energy levels
A.remains constant
B.decreases
C.increases
D.sometimes increases sometimes decreases

Answer 1

Solution

Since, we know that the energy levels of an electron around a nucleus is represented by,
${E_n} = \dfrac{{m{e^4}{Z^2}}}{{8{n^2}{h^2}\varepsilon _0^2}}$
And the energy of a given atomic orbital is therefore proportional to the inverse square of the principal quantum number i.e., ${E_n}\alpha \dfrac{1}{{{n^2}}}$

Complete step by step answer:
The energy levels of an electron around a nucleus:
${E_n} = \dfrac{{m{e^4}{Z^2}}}{{8{n^2}{h^2}\varepsilon _0^2}}$
Where,
m - the rest mass of the electron;
e - the elementary charge;
Z - the atomic number;
${\varepsilon _0}$ - the permittivity of free space;
h - the Planck constant;
n - the principal quantum number.
Where variables have their usual meanings
$\Rightarrow {E_n}\alpha \dfrac{1}{{{n^2}}}$
The energy difference between adjacent levels with quantum numbers n and (n-1): $\Delta En,n - 1 = En - En - 1 = - \dfrac{{m{e^4}{Z^2}}}{{8{h^2}\varepsilon _0^2}}[\dfrac{1}{{{{(n - 1)}^2}}} + \dfrac{1}{{{n^2}}} = \dfrac{{2n - 1}}{{{n^2} - 1}}$
This can be approximated to $\dfrac{2}{n}$ when n is very large.
Thus, energy difference between consecutive levels decreases as n increases.
Energy of levels in hydrogen atom is $\dfrac{{ - 13.6}}{{{n^2}}}$
So, as the n increases, energy between the consecutive levels will decrease.
Because energy decreases as $\dfrac{1}{{{n^2}}}$
Hence, with increasing quantum numbers the energy difference between adjacent levels in atoms decreases.

Therefore, the correct answer is option (B).

Note:
The energy which is represented by ${E_n} = - \:\dfrac{{m{e^4}{Z^2}}}{{8{n^2}{h^2}\varepsilon _0^2}}$ is negative and it approaches zero as the quantum number n approaches infinity. Because the hydrogen atom is used as a foundation for multi-electron systems, it is useful to remember the total energy (binding energy) of the ground state hydrogen atom, ${E_H} = - 13.6eV$ . The spacing between electronic energy levels for small values of n is very large while the spacing between higher energy levels gets smaller very rapidly.