For a given material, the energy and wavelength of characteristic x-rays satisfy:

E (K_{α})

E (K_{β})

E (K_{γ})

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E (M_{α})

E (L_{α})

E (K_{α})

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λ (K_{α})

λ (K_{β})

λ (K_{γ})

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λ (M_{α})

λ (L_{α})

λ (K_{α})

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Solution

The correct option is D $λ (M_{α})$ > $λ (L_{α})$ > $λ (K_{α})$

Quantitatively,
$E (K_{α}) = E_{K} - E_{L}$
$E (K_{β}) = E_{K} - E_{M}$
$E (K_{γ}) = E_{K} - E_{N}$
Clearly,
$E (K_{α})$ < $E (K_{β})$ < $E (K_{γ}) .$ (1)
Since energy is inversely proportional to wavelength, by the relation E = $\frac{h c}{λ}$ , relation (1) will imply,
$λ (K_{α})$ > $λ (K_{β})$ < $λ (K_{γ}) .$ (2)
What now about the L and M lines? The diffference between the energy levels decreases as the principal quantum number n increases. This will mean -
$(E_{M} - E_{N})$ < $(E_{L} - E_{M})$ < $(E_{K} - E_{L})$
$\to$ $E (M_{α}) < E (L_{α}) < E (K_{α})$ (3)
$\to$ $λ (M_{α})$ > $λ (L_{α})$ < $λ (K_{α})$ (4)
Since energy and wavelength share a reciprocal relation.

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