29.14.3Estimate of Atomic Decay Rate
We have the formula
Γtot=e^2 (Ei−En)
2 π ̄h^2 m^2 c^3∫
dΩγ|〈φn|e−i(
~k·~r)
ˆǫ·~pe|φi〉|^2Lets make some approximations.
ˆǫ·~p ≈ |p|=m|v|≈mαc=αmc~k·~r ≈ ka 0 = ̄hω
̄hca 0 ≈1
2 α(^2) mc 2
̄hc
a 0 =
α^2 mc^2
2 ̄hc
̄h
αmc
=
α
2
e−i(
~k·~r)
≈ e
iα 2
≈1 +
iα
2≈ 1
Γtot =e^2 (Ei−En)
2 π ̄h^2 m^2 c^3(4π)|αmc|^2=
α(Ei−En)
2 π ̄hm^2 c^2(4π)|αmc|^2=
α(^12 α^2 mc^2 )
2 π ̄hm^2 c^2(4π)|αmc|^2=
α^5 mc^2
̄h=α^5 mc^2 c
̄hc=(0.51 MeV)3× 1010 cm/sec
(137^5 )(197 MeV F)
(10−^13 F/cm)≈ 2 × 1010 sec−^1This gives a life time of about 50 psec.
29.15Homework Problems
- The interaction term for Electric Quadrupole transitions correspond to a linear combination
of spherical harmonics,Y 2 m, and are parity even. Find the selection rules for E2 transitions. - Magnetic dipole transitions are due to an axial vector operator and hence are proportional to
theY 1 mbut do not change parity (unlike a vector operator). What are theM1 selection rules? - Draw the energy level diagram for hydrogen up ton= 3. Show the allowed E1 transitions.
Use another color to show the allowed E2 and M1 transitions. - Calculate the decay rate for the 3p→ 1 stransition.
- Calculate the decay rate for the 3d→ 2 ptransition in hydrogen.
- Assume that we prepare Hydrogen atoms in theψnℓm=ψ 211 state. We set up an experiment
with the atoms at the origin and detectors sensitive to the polariztion along each of the 3
coordinate axes. What is the probability that a photon with its wave vector pointing along
the axis will be Left Circularly Polarized? - Photons from the 3p → 1 stransition are observed coming from the sun. Quantitatively
compare the natural line width to the widths from Doppler broadening and collision broadening
expected for radiation from the sun’s surface.