An electron from various excited states of hydrogen atom emit radiation to come to the ground state. Let $λ_{n}, λ_{g}$ be the de Broglie wavelength of the electron in the $n^{th}$ state and the ground state respectively. Let $A_{n}$ be the wavelength of the emitted photon in the transition from the $n^{th}$ state to the ground state. For large $n$ , ( $A, B$ are constants)

$\land {^{2}}_{n} \approx A + {Bλ}^{2}_{n}$

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$\land^{2} n \approx λ$

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$\land_{n} \approx A + (B / {λ^{2}}_{n})$

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$\land_{n} \approx A + {Bλ}_{n}$

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Solution

The correct option is C
$\land_{n} \approx A + (B / {λ^{2}}_{n})$

The above question can be solved as:
Step 1:
We know from Bohr's Postulates:
Angular velocity $= m v r = \frac{n h}{2 π}$
Step 2:
And now from De Broglie's Theory
$λ_{de broglie}$ $= \frac{h}{p} = \frac{2 πr}{h}$ ……. $1$
$λ_{n} =$ $\frac{2 {πr}_{n}}{n}$ …………………. $2$
from $1$ and $2$ we get
$λ_{g} = \frac{2 {πr}_{1}}{1} = 2 {πr}_{1}$
Step 3:
We know from the Rydberg equation,
$\frac{1}{Λ_{n}} = R [1 - \frac{1}{n^{2}}]$
, $\frac{λ_{g}}{λ_{n}} = \frac{r_{n}}{n r_{1}} = n$
Now,
$Λ_{n} = \frac{n^{2}}{R (n^{2} - 1)} = \frac{1}{R} [\frac{λ_{n}^{2}}{λ_{n}^{2} - λ_{g}^{2}}]$
$= \frac{1}{R} [\frac{1}{1 - {(\frac{λ_{g}}{λ_{n}})}^{2}}]$
$≃ \frac{1}{R} [1 + {(\frac{λ_{g}}{λ_{n}})}^{2}]$
$Λ_{n} ≃ A + \frac{B}{λ_{n}^{2}}$
Therefore, option C is correct.

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