2.3 Solutions 117
Further from (2) d(Δω)=dω. The relative distribution of Doppler shift is
dN
N
=
exp
[
−
(
Δω
ΔωD
) 2 ]
√
π
dω
ΔωD
(6)
Thus a Gaussian distribution is produced in the Doppler shift due to the
random thermal motion of the source (Fig. 2.4).
The intensity of radiation is
I(ω)=
exp
[
−
(
Δω
ΔωD
) 2 ]
ΔωD
√
π
(7)
centered around the unshifted frequencyω 0. The width of the distribution at
the frequencies whereI(ω) falls to half the central intensityI(ω 0 ) is known as
the half width
Doppler half width=2(ln2)^1 /^2 ΔωD
= 2 ω 0
(
2 kT ln 2
Mc^2
) 1 / 2
(8)
Thermal broadening is most pronounced for light atoms such as hydrogen and
high temperatures, for example the Hαline (6,563A) has a Doppler width of ̊
0.6A at 400 K. ̊
2.49 Lande’ g-factor is
g= 1 +j(j+1)+s(s+1)−l(l+1)/ 2 j(j+1)
For the term^2 P 3 / 2 ,l= 1 ,J=^32 ,s=^12 andg=^43
For^2 S 1 / 2 ,l= 0 ,j=^12 ,s=^12 andg= 2
Fig. 2.5Anamolous Zeeman
effect in an alkali atom. The
lines are not equidistant