(Adapted from Tes)
The electron first absorbs a photon and is excited to #n = 3# (a).
Then it emits one photon when it drops to #n=2# (b) and another when it drops from #n=2# to #n=1# (c).
(a) Excitation to #n=2#
The wavelength is given by the Rydberg formula
#color(blue)(bar(ul(|color(white)(a/a) 1/λ = R(1/n_2^2 -1/n_1^2)color(white)(a/a)|)))" "#
where
#R =# the Rydberg constant (#1.097 × 10^7color(white)(l) "m"^"-1"#)
#n_1 =# the upper energy level
#n_2 =# the lower energy level
For this part,
#n_1 = 3#
#n_2 = 1#
#1/λ = 1.097 × 10^7color(white)(l) "m"^"-1" × (1/1^2 -1/3^2) = 1.097 × 10^7color(white)(l) "m"^"-1" (1/1-1/9)#
#= 1.097 × 10^7color(white)(l) "m"^"-1" × (9-1)/(9×1) = 1.097 × 10^7color(white)(l) "m"^"-1" × 8/9 = 9.751 × 10^6 color(white)(l)"m"^"-1"#
#λ = 1/(9.751 × 10^6 color(white)(l)"m"^"-1") = 1.026 × 10^"-7"color(white)(l) "m" = "102.6 nm"#
(b) Dropping from #n=3# to #n = 2#
#1/λ = 1.097 × 10^7color(white)(l) "m"^"-1" × (1/2^2 -1/3^2) = 1.097 × 10^7color(white)(l) "m"^"-1" (1/4-1/9)#
#= 1.097 × 10^7color(white)(l) "m"^"-1" × (9-4)/(9×4) = 1.097 × 10^7color(white)(l) "m"^"-1" × 5/36 = 1.524 × 10^6 color(white)(l)"m"^"-1"#
#λ = 1/(1.524 × 10^6 color(white)(l)"m"^"-1") = 6.563 × 10^"-7"color(white)(l) "m" = "656.3 nm"#
(c) Dropping from #n=2# to #n = 1#
#1/λ = 1.097 × 10^7color(white)(l) "m"^"-1" × (1/1^2 -1/2^2) = 1.097 × 10^7color(white)(l) "m"^"-1" (1/1-1/4)#
#= 1.097 × 10^7color(white)(l) "m"^"-1" × (4-1)/(4×1) = 1.097 × 10^7color(white)(l) "m"^"-1" × 3/4 = 8.228 × 10^6 color(white)(l)"m"^"-1"#
#λ = 1/(8.228 × 10^6 color(white)(l)"m"^"-1") = 1.215 × 10^"-7"color(white)(l) "m" = "121.5 nm"#
