Interaction of an atom with an electromagnetic field

This section introduces the interaction of atoms with radiative modes of the electromagnetic field.

Introduction: Spontaneous and Stimulated Emission

Einstein's 1917 paper on the theory of radiation ^[1] provided seminal concepts for the quantum theory of radiation. It also anticipated devices such as the laser, and pointed the way to the field of laser-cooling of atoms. In it, he set out to answer two questions:

1) How do the internal states of an atom that radiates and absorbs energy come into equilibrium with a thermal radiation field? (In answering this question Einstein invented the concept of spontaneous emission)

2) How do the translational states of an atom in thermal equilibrium (i.e. states obeying the Maxwell-Boltzmann Law for the distribution of velocities) come into thermal equilibrium with a radiation field? (In answering this question, Einstein introduced the concept of photon recoil. He also demonstrated that the field itself must obey the Planck radiation law.)

The first part of Einstein's paper, which addresses question 1), is well known, but the second part, which addresses question 2), is every bit as germane to contemporary atom/optical physics. Because the paper preceded the creation of quantum mechanics there was no way for him to calculate transition rates. However, his arguments are based on general statistical principles and provide the foundation for interpreting the quantum mechanical results.

Einstein considered a system of ${\displaystyle N}$ atoms in thermal equilibrium with a radiation field. The system has two levels (an energy level consists of all of the states that have a given energy; the number of quantum states in a given level is its multiplicity.) with energies ${\displaystyle E_{b}}$ and ${\displaystyle E_{a}}$, with ${\displaystyle E_{b}>E_{a}}$, and ${\displaystyle E_{b}-E_{a}=\hbar \omega }$. The numbers of atoms in the two levels are related by ${\displaystyle N_{b}+N_{a}=N}$. Einstein assumed the Planck radiation law for the spectral energy density temperature. For radiation in thermal equilibrium at temperature ${\displaystyle T}$, the energy per unit volume in wavelength range ${\displaystyle d\omega }$ is:

<equation id="erad1" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \rho _{E}(\omega )d\omega ={\frac {\hbar \omega ^{3}}{\pi ^{2}c^{3}}}{\frac {1}{{\rm {exp}}(\hbar \omega /kT)-1}}d\omega .\end{aligned}}}$ </equation>

The mean occupation number of a harmonic oscillator at temperature ${\displaystyle T}$, which can be interpreted as the mean number of photons in one mode of the radiation field, is

<equation id="erad2" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bar {n}}={\frac {1}{{\rm {exp}}(\hbar \omega /kT)-1}}.\end{aligned}}}$ </equation>

According to the Boltzmann Law of statistical mechanics, in thermal equilibrium the populations of the two levels are related by

<equation id="erad3" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\frac {N_{b}}{N_{a}}}={\frac {g_{b}}{g_{a}}}e^{-(E_{b}-E_{a})/kT}={\frac {g_{b}}{g_{a}}}e^{-\hbar \omega /kT}.\end{aligned}}}$ </equation>

Here ${\displaystyle g_{b}}$ and ${\displaystyle g_{a}}$ are the multiplicities of the two levels. The last step assumes the Bohr frequency condition, ${\displaystyle \omega =(E_{b}-E_{a})\ \hbar }$. However, Einstein's paper actually derives this relation independently.

According to classical theory, an oscillator can exchange energy with the radiation field at a rate that is proportional to the spectral density of radiation. The rates for absorption and emission are equal. The population transfer rate equation is thus predicted to be

<equation id="erad4" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\dot {N}}_{b}=-{\rho _{E}(\omega )B_{ba}}N_{b}+\rho _{E}(\omega )B_{ab}N_{a}=-{\dot {N}}_{a}.\end{aligned}}}$ </equation>

This equation is compatible with <xr id="erad1"/>, <xr id="erad2"/>, <xr id="erad3"/>  it follows that

<equation id=" erl5" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ g_{b}B_{ba}&=&g_{a}B_{ab}\\{\frac {\hbar \omega ^{3}}{\pi ^{2}c^{3}}}B_{ba}&=&A_{ba}\\\rho _{E}(\omega )B_{ba}&=&{\bar {n}}A_{ba}\\\end{aligned}}}$ </equation>

Consequently, the rate of transition ${\displaystyle b\rightarrow a}$ is

<equation id=" erl6" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ B_{ba}\rho _{E}(\omega )+A_{ba}=({\bar {n}}+1)A_{ba},\end{aligned}}}$ </equation>

while the rate of absorption is

<equation id=" erl7" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ B_{ab}\rho _{E}(\omega )={\frac {g_{b}}{g_{a}}}{\bar {n}}A_{ba}\end{aligned}}}$ </equation>

If we consider emission and absorption between single states by taking ${\displaystyle g_{b}=g_{a}=1}$, then the ratio of rate of emission to rate of absorption is ${\displaystyle ({\bar {n}}+1)/{\bar {n}}}$.

This argument reveals the fundamental role of spontaneous emission. Without it, atomic systems could not achieve thermal equilibrium with a radiation field. Thermal equilibrium requires some form of dissipation, and dissipation is equivalent to having an irreversible process. Spontaneous emission is the fundamental irreversible process in nature. The reason that it is irreversible is that once a photon is radiated into the vacuum, the probability that it will ever be reabsorbed is zero: there are an infinity of vacuum modes available for emission but only one mode for absorption. If the vacuum modes are limited, for instance by cavity effects, the number of modes becomes finite and equilibrium is never truly achieved. In the limit of only a single mode, the motion becomes reversible.

The identification of the Einstein ${\displaystyle A}$ coefficient with the rate of spontaneous emission is so well established that we shall henceforth use the symbol ${\displaystyle A_{ba}}$ to denote the spontaneous decay rate from state ${\displaystyle b}$ to ${\displaystyle a}$. The radiative lifetime for such a transition is ${\displaystyle \tau _{ba}=A_{ba}^{-1}}$.

Here, Einstein came to a halt. Lacking quantum theory, there was no way to calculate ${\displaystyle A_{ba}}$.

Quantum Theory of Absorption and Emission

We shall start by describing the behavior of an atom in a classical electromagnetic field. Although treating the field classically while treating the atom quantum mechanically is fundamentally inconsistent, it provides a natural and intuitive approach to the problem. Furthermore, it is completely justified in cases where the radiation fields are large, in the sense that there are many photons in each mode, as for instance, in the case of microwave or laser spectroscopy. There is, however, one important process that this approach cannot deal with satisfactorily. This is spontaneous emission, which we shall treat later using a quantized field. Nevertheless, phenomenological properties such as selection rules, radiation rates and cross sections, can be developed naturally with this approach.

The classical E-M field

Our starting point is Maxwell's equations (S.I. units):

<equation id="Maxwell" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \nabla \cdot {\bf {E}}&=&\rho /\epsilon _{0}\\\nabla \cdot {\bf {B}}&=&0\\\nabla \times {\bf {E}}&=&-{\frac {\partial {\bf {B}}}{\partial t}}\\\nabla \times {\bf {B}}&=&{\frac {1}{c^{2}}}{\frac {\partial {\bf {E}}}{\partial t}}+\mu _{0}{\bf {J}}\end{aligned}}}$ </equation>

The charge density ${\displaystyle \rho }$ and current density J obey the continuity equation

<equation id=" wd2" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \nabla \cdot {\bf {J}}+{\frac {\partial \rho }{\partial t}}=0\end{aligned}}}$ </equation>

Introducing the vector potential A and the scalar potential ${\displaystyle \psi }$, we have

<equation id=" wd3" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bf {E}}&=&-\nabla \psi -{\frac {\partial {\bf {A}}}{\partial t}}\\{\bf {B}}&=&\nabla \times {\bf {A}}\end{aligned}}}$ </equation>

We are free to change the potentials by a gauge transformation:

<equation id=" wd4" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bf {A}}^{\prime }={\bf {A}}+\nabla \Lambda ,~~~~~\psi ^{\prime }=\psi -{\frac {\partial \Lambda }{\partial t}}\end{aligned}}}$ </equation>

where ${\displaystyle \Lambda }$ is a scalar function. This transformation leaves the fields invariant, but changes the form of the dynamical equation. We shall work in the Coulomb gauge (often called the radiation gauge), defined by

<equation id=" wd5" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \nabla \cdot {\bf {A}}=0\end{aligned}}}$ </equation>

In free space, A obeys the wave equation

<equation id=" wd6" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \nabla ^{2}{\bf {A}}={\frac {1}{c^{2}}}{\frac {\partial ^{2}{\bf {A}}}{\partial t^{2}}}\end{aligned}}}$ </equation>

Because ${\displaystyle \nabla \cdot {\bf {A}}=0}$, A is transverse. We take a propagating plane wave solution of the form

<equation id="A-field" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bf {A}}(r,t)=A{\bf {\hat {e}}}\cos({\bf {k}}\cdot {\bf {r}}-\omega t)=A{\bf {\hat {e}}}{\frac {1}{2}}\left[e^{i({\bf {k}}\cdot {\bf {r}}-\omega t)}+e^{-i({\bf {k}}\cdot {\bf {r}}-\omega t)}\right],\end{aligned}}}$ </equation>

where ${\displaystyle k^{2}=\omega ^{2}/c^{2}}$ and ${\displaystyle {\bf {\hat {e}}}\cdot {\bf {k}}=0}$. For a linearly polarized field, the polarization vector ${\displaystyle {\bf {\hat {e}}}}$ is real. For an elliptically polarized field it is complex, and for a circularly polarized field it is given by ${\displaystyle {\bf {\hat {e}}}=({\bf {\hat {x}}}\pm i{\bf {\hat {y}}})/{\sqrt {2}}}$ , where the + and ${\displaystyle -}$ signs correspond to positive and negative helicity, respectively. (Alternatively, they correspond to left and right hand circular polarization, respectively, the sign convention being a tradition from optics.) The electric and magnetic fields are then given by

<equation id="E-field" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bf {E}}(r,t)=\omega A{\bf {\hat {e}}}\sin({\bf {k}}\cdot {\bf {r}}-\omega t)=-i\omega A{\bf {\hat {e}}}{\frac {1}{2}}\left[e^{i({\bf {k}}\cdot {\bf {r}}-\omega t)}-e^{-i({\bf {k}}\cdot {\bf {r}}-\omega t)}\right].\end{aligned}}}$ </equation>

<equation id="B-field" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bf {B}}(r,t)=k({\bf {\hat {k}}}\times {\bf {\hat {e}}})\sin({\bf {k}}\cdot {\bf {r}}-\omega t)=-ikA({\bf {\hat {k}}}\times {\bf {\hat {e}}}){\frac {1}{2}}\left[e^{i({\bf {k}}\cdot {\bf {r}}-\omega t)}-e^{-i({\bf {k}}\cdot {\bf {r}}-\omega t)}\right].\end{aligned}}}$ </equation>

The time average Poynting vector is

<equation id=" wd9" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bf {S}}={\frac {\epsilon _{0}c^{2}}{2}}({{\bf {E}}\times {\bf {B}}^{*})}={\frac {\epsilon _{0}c}{2}}\omega ^{2}A^{2}{\bf {\hat {k}}}.\end{aligned}}}$ </equation>

The average energy density in the wave is given by

<equation id="energy-density" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ u=\omega ^{2}{\frac {\epsilon _{0}}{2}}A^{2}{\bf {\hat {k}}}.\end{aligned}}}$ </equation>

Interaction of an electromagnetic wave and an atom

The behavior of charged particles in an electromagnetic field is correctly described by Hamilton's equations provided that the canonical momentum is redefined:

<equation id=" int1" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bf {p}}_{\rm {can}}={\bf {p}}_{\rm {kin}}+q{\bf {A}}\end{aligned}}}$ </equation>

The kinetic energy is ${\displaystyle {\bf {p}}_{\rm {kin}}^{2}/2m}$. Taking ${\displaystyle q=-e}$, the Hamiltonian for an atom in an electromagnetic field in free space is

<equation id=" int2" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ H={\frac {1}{2m}}\sum _{j=1}^{N}{\left({\bf {p}}_{j}+e{\bf {A}}(r_{j})\right)^{2}}+\sum _{j=1}^{N}V({\bf {r}}_{j}),\end{aligned}}}$ </equation>

where ${\displaystyle V({\bf {r}}_{j})}$ describes the potential energy due to internal interactions. We are neglecting spin interactions.

Expanding and rearranging, we have

<equation id=" int3" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ H&=&\sum _{j=1}^{N}{\frac {{\bf {p}}_{j}^{2}}{2m}}+V({\bf {r}}_{j})+{\frac {e}{2m}}\sum _{j=1}^{N}{\left({\bf {p}}_{j}\cdot {\bf {A}}({\bf {r}}_{j})+{\bf {A}}({\bf {r}}_{j})\cdot {\bf {p}}_{j}\right)}+{\frac {e^{2}}{2m}}\sum _{j=1}^{N}A_{j}^{2}({\bf {r}})\\&=&H_{0}+H_{\rm {int}}+H^{(2)}.\end{aligned}}}$ </equation>

Here, ${\displaystyle {\bf {p}}_{j}=-i\hbar \nabla _{j}}$. Consequently, ${\displaystyle H_{0}}$ describes the unperturbed atom. ${\displaystyle H_{\rm {int}}}$ describes the atom's interaction with the field. ${\displaystyle H^{(2)}}$, which is second order in A, plays a role only at very high intensities. (In a static magnetic field, however, ${\displaystyle H^{(2)}}$ gives rise to diamagnetism.)

Because we are working in the Coulomb gauge, ${\displaystyle \nabla \cdot {\bf {A}}=0}$ so that A and p commute. We have

<equation id=" int4" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ H_{\rm {int}}={\frac {eA}{m}}{\hat {\bf {e}}}\cdot {\bf {p}}\cos({\bf {k}}\cdot {\bf {r}}-\omega t).\end{aligned}}}$ </equation>

It is convenient to write the matrix element between states ${\displaystyle |a\rangle }$ and ${\displaystyle |b\rangle }$ in the form

<equation id=" int5" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \langle b|H_{\rm {int}}|a\rangle ={\frac {1}{2}}H_{ba}e^{-i\omega t}+{\frac {1}{2}}H_{ba}e^{+i\omega t},\end{aligned}}}$ </equation>

where

<equation id=" int6" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ H_{ba}={\frac {eA}{m}}{\bf {\hat {e}}}\,\langle b|{\bf {p}}\,e^{i{\bf {k}}\cdot {\bf {r}}}|a\rangle .\end{aligned}}}$ </equation>

Atomic dimensions are small compared to the wavelength of radiation involved in optical transitions. The scale of the ratio is set by ${\displaystyle \alpha \approx 1/137}$. Consequently, when the matrix element in <xr id="int6"/> is evaluated, the wave function vanishes except in the region where ${\displaystyle {\bf {k}}\cdot {\bf {r}}=2\pi r/\lambda \ll 1}$. It is therefore appropriate to expand the exponential:

<equation id=" int7" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ H_{ba}={\frac {eA}{m}}{\bf {\hat {e}}}\cdot \langle b|{\bf {p}}(1+i{\bf {k}}\cdot {\bf {r}}-1/2({\bf {k}}\cdot {\bf {r}})^{2}+\cdots )|a\rangle \end{aligned}}}$ </equation>

Unless ${\displaystyle \langle b|{\bf {p}}|a\rangle }$ vanishes, for instance due to parity considerations, the leading term dominates and we can neglect the others. For reasons that will become clear, this is called the dipole approximation. This is by far the most important situation, and we shall defer consideration of the higher order terms. In the dipole approximation we have

<equation id=" int8" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ H_{ba}={\frac {eA}{m}}{\bf {\hat {e}}}\cdot \langle b|{\bf {p}}|a\rangle ={\frac {-ieE}{m\omega }}{\bf {\hat {e}}}\cdot \langle b|{\bf {p}}|a\rangle \end{aligned}}}$ </equation>

where we have used, from <xr id="E-field"/>, ${\displaystyle A=-iE/\omega }$. It can be shown (i.e. left as exercise) that the matrix element of p can be transfomred into a matrix element for ${\displaystyle {\bf {r}}}$:

<equation id=" int9" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \langle b|{\bf {p}}|a\rangle =-im\omega _{ab}\langle b|{\bf {r}}|a\rangle =+im\omega _{ba}\langle b|{\bf {r}}|a\rangle \end{aligned}}}$ </equation>

This results in

<equation id=" int10" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ H_{ba}={\frac {eE\omega _{ba}}{\omega }}{\bf {\hat {e}}}\cdot \langle b|{\bf {r}}|a\rangle \end{aligned}}}$ </equation>

We will be interested in resonance phenomena in which ${\displaystyle \omega \approx \omega _{ba}}$. Consequently,

<equation id=" int11" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ H_{ba}=+e{\bf {E}}_{0}\cdot \langle b|{\bf {r}}|a\rangle =-{\bf {d}}_{ba}\cdot {\bf {E}}\end{aligned}}}$ </equation>

where d is the dipole operator, ${\displaystyle {\bf {d}}=-e{\bf {r}}}$. Displaying the time dependence explictlty, we have

<equation id=" int12" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ H_{ba}^{\prime }=-{\bf {d}}_{ba}\cdot {\bf {E}}_{0}e^{-i\omega t}.\end{aligned}}}$ </equation>

However, it is important to bear in mind that this is only the first term in a series, and that if it vanishes the higher order terms will contribute a perturbation at the driving frequency.

${\displaystyle H_{ba}}$ appears as a matrix element of the momentum operator p in <xr id="int8"/>, and of the dipole operator r in <xr id="int11"/>. These matrix elements look different and depend on different parts of the wave function. The momentum operator emphasizes the curvature of the wave function, which is largest at small distances, whereas the dipole operator evaluates the moment of the charge distribution, i.e. the long range behavior. In practice, the accuracy of a calculation can depend significantly on which operator is used.

Quantization of the radiation field

We shall consider a single mode of the radiation field. This means a single value of the wave vector k, and one of the two orthogonal transverse polarization vectors ${\displaystyle {\bf {\hat {e}}}}$. The radiation field is described by a plane wave vector potential of the form <xr id="A-field"/>. We assume that k obeys a periodic boundary or condition, ${\displaystyle k_{x}L_{x}=2\pi n_{x}}$, etc. (For any k, we can choose boundaries ${\displaystyle L_{x},L_{y},L_{z}}$ to satisfy this.) The time averaged energy density is given by <xr id="energy-density"/>, and the total energy in the volume V defined by these boundaries is

<equation id="energy-total" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ U={\frac {\epsilon _{0}}{2}}\omega ^{2}A^{2}V,\end{aligned}}}$ </equation>

where ${\displaystyle A^{2}}$ is the mean squared value of ${\displaystyle A}$ averaged over the spatial mode. We now make a formal connection between the radiation field and a harmonic oscillator. We define variables Q and P by

<equation id=" qrd5" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ A={\frac {1}{\omega }}{\sqrt {\frac {1}{\epsilon _{o}V}}}(\omega Q+iP),~~A^{*}={\frac {1}{\omega }}{\sqrt {\frac {1}{\epsilon _{o}V}}}(\omega Q-iP).\end{aligned}}}$ </equation>

Then, from <xr id="energy-total"/>, we find

<equation id=" qrd6" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ U={\frac {1}{2}}(\omega ^{2}Q^{2}+P^{2}).\end{aligned}}}$ </equation>

This describes the energy of a harmonic oscillator having unit mass. We quantize the oscillator in the usual fashion by treating Q and P as operators, with

<equation id=" qrd7" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ P=-i\hbar {\frac {\partial }{\partial Q}},~~~[Q,P]=i\hbar .\end{aligned}}}$ </equation>

We introduce the operators ${\displaystyle a}$ and ${\displaystyle a^{\dagger }}$ defined by

<equation id=" qrd8" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ a={\frac {1}{\sqrt {2\hbar \omega }}}(\omega Q+iP)\end{aligned}}}$ </equation>

<equation id=" qrd9" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ a^{\dagger }={\frac {1}{\sqrt {2\hbar \omega }}}(\omega Q-iP)\end{aligned}}}$ </equation>

The fundamental commutation rule is

<equation id=" qrd10" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ [a,a^{\dagger }]=1\end{aligned}}}$ </equation>

from which the following can be deduced:

<equation id=" qrd11" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ H={\frac {1}{2}}\hbar \omega [a^{\dagger }a+aa^{\dagger }]=\hbar \omega \left[a^{\dagger }a+{\frac {1}{2}}\right]=\hbar \omega \left[N+{\frac {1}{2}}\right]\end{aligned}}}$ </equation>

where the number operator ${\displaystyle N=a^{\dagger }a}$ obeys

<equation id=" qrd12" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ N|n\rangle =n|n\rangle \end{aligned}}}$ </equation>

We also have

<equation id=" qrd13" noautocaption>(%i) ${\displaystyle {\begin{aligned}\langle n-1|a|n\rangle &=&{\sqrt {n}}\\\langle n+1|a^{\dagger }|n\rangle &=&{\sqrt {n+1}}\\\langle n|a^{\dagger }a|n\rangle &=&n\\\langle n|aa^{\dagger }|n\rangle &=&n+1\\\langle n|H|n\rangle &=&\hbar \omega \left(n+{\frac {1}{2}}\right)\\\ \langle n|a|n\rangle &=&\langle n|a^{\dagger }|n\rangle =0\end{aligned}}}$ </equation>

The operators ${\displaystyle a}$ and ${\displaystyle a^{\dagger }}$ are called the annihilation and creation operators, respectively. We can express the vector potential and electric field in terms of ${\displaystyle a}$ and ${\displaystyle a^{\dagger }}$ as follows

<equation id=" part1" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ A={\frac {1}{\omega {\sqrt {\epsilon _{o}V}}}}(\omega Q+iP)={\sqrt {\frac {2\hbar }{\omega \epsilon _{o}V}}}a\end{aligned}}}$ </equation>

<equation id=" part2" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ A^{\dagger }={\frac {1}{\omega {\sqrt {\epsilon _{o}V}}}}(\omega Q-iP)={\sqrt {\frac {2\hbar }{\omega \epsilon _{o}V}}}a^{\dagger }\end{aligned}}}$ </equation>

<equation id=" part3" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bf {E}}=-i{\sqrt {\frac {\hbar \omega }{2\epsilon _{o}V}}}{\left[a{\bf {\hat {e}}}e^{i({\bf {k}}\cdot {\bf {r}}-\omega t)}-a^{\dagger }{\bf {\hat {e}}}^{*}e^{-i({\bf {k}}\cdot {\bf {r}}-\omega t)}\right]}\end{aligned}}}$ </equation>

In the dipole limit we can take ${\displaystyle e^{i{\bf {k}}\cdot {\bf {r}}}=1}$. Then

<equation id=" part3" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bf {E}}=-i{\sqrt {\frac {\hbar \omega }{2\epsilon _{o}V}}}\left[a{\bf {\hat {e}}}e^{-i\omega t}-a^{\dagger }{\bf {\hat {e}}}^{*}e^{i\omega t}\right]\end{aligned}}}$ </equation>

The interaction Hamiltonian is,

<equation id=" qrd16" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ H_{\rm {int}}=-ie{\sqrt {\frac {\hbar \omega }{2\epsilon _{o}V}}}{\bf {r}}\cdot {\left[a{\bf {\hat {e}}}e^{-i\omega t}-a^{\dagger }{\bf {\hat {e}}}^{*}e^{+i\omega t}\right]},\end{aligned}}}$ </equation>

where we have written the dipole operator as ${\displaystyle {\bf {d}}=-e{\bf {r}}}$.

Interaction of a two-level system and a single mode of the radiation field

We consider a two-state atomic system ${\displaystyle |a\rangle }$, ${\displaystyle |b\rangle }$ and a radiation field described by ${\displaystyle |n\rangle ,\ n=0,1,2\dots }$ The states of the total system can be taken to be

<equation id=" vac1" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ |I\rangle =|a,\ n\rangle =|a\rangle \ |n\rangle ,~~~|F\rangle =|b,\ n^{\prime }\rangle =|b\rangle \ |n^{\prime }\rangle .\end{aligned}}}$ </equation>

We shall take ${\displaystyle {\bf {\hat {e}}}={\bf {\hat {z}}}}$. Then

<equation id=" vac2" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \langle F|H_{\rm {int}}|I\rangle =-iez_{ab}{\sqrt {\frac {2\pi \hbar \omega }{V}}}\langle n^{\prime }|ae^{-i\omega t}-a^{\dagger }e^{i\omega t}|n\rangle e^{-i\omega _{ab}t}\end{aligned}}}$ </equation>

The first term in the bracket obeys the selection rule ${\displaystyle n^{\prime }=n-1}$. This corresponds to loss of one photon from the field and absorption of one photon by the atom. The second term obeys ${\displaystyle n^{\prime }=n+1}$. This corresponds to emission of a photon by the atom. Using <xr id="qrd13"/>, we have

<equation id=" vac3" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \langle F|H_{\rm {int}}|I\rangle =-iez_{ab}{\sqrt {\frac {2\pi \hbar \omega }{V}}}{\left({\sqrt {n}}\,\delta _{n\prime ,n-1}\ e^{-i\omega t}-{\sqrt {n+1}}\,\delta _{n\prime ,n+1}e^{+i\omega t}\right)}\ e^{-i\omega _{ab}t}\end{aligned}}}$ </equation>

Transitions occur when the total time dependence is zero, or near zero. Thus absorption occurs when ${\displaystyle \omega =-\omega _{ab}}$, or ${\displaystyle E_{a}+\hbar \omega =E_{b}}$. As we expect, energy is conserved. Similarly, emission occurs when ${\displaystyle \omega =+\omega _{ab}}$, or ${\displaystyle E_{a}-\hbar \omega =E_{b}}$.

A particularly interesting case occurs when ${\displaystyle n=0}$, i.e. the field is initially in the vacuum state, and ${\displaystyle \omega =\omega _{ab}}$. Then

<equation id=" vac4" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \langle F|H_{\rm {int}}|I\rangle =iez_{ab}{\sqrt {\frac {2\pi \hbar \omega }{V}}}\equiv H_{FI}^{0}\end{aligned}}}$ </equation>

The situation describes a constant perturbation ${\displaystyle H_{FI}^{0}}$ coupling the two states ${\displaystyle I=|a,n=0\rangle }$ and ${\displaystyle F=|b,n^{\prime }=1\rangle }$. The states are degenerate because ${\displaystyle E_{a}=E_{b}+\hbar \omega }$. Consequently, ${\displaystyle E_{a}}$ is the upper of the two atomic energy levels.

The system is composed of two degenerate eigenstates, but due to the coupling of the field, the degeneracy is split. The eigenstates are symmetric and antisymmetric combinations of the initial states, and we can label them as

<equation id=" vac5" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ |\pm \rangle ={\frac {1}{\sqrt {2}}}(|I\rangle \pm |F\rangle )={\frac {1}{\sqrt {2}}}(|a,0\rangle \pm |b,1\rangle ).\end{aligned}}}$ </equation>

The energies of these states are

<equation id=" vac6" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ E_{\pm }=\pm |H_{FI}^{0}|\end{aligned}}}$ </equation>

If at ${\displaystyle t=0}$, the atom is in state ${\displaystyle |a\rangle }$ which means that the radiation field is in state ${\displaystyle |0\rangle }$ then the system is in a superposition state:

<equation id=" vac7" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \psi (0)={\frac {1}{\sqrt {2}}}(|+\rangle +|-\rangle ).\end{aligned}}}$ </equation>

The time evolution of this superposition is given by

<equation id=" vac8" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \psi (t)={\frac {1}{\sqrt {2}}}\left(|+\rangle e^{i\Omega /2t}+|-\rangle e^{-i\Omega /2t}\right)\end{aligned}}}$ </equation>

where ${\displaystyle \Omega /2=|H_{FI}^{0}|/\hbar =ez_{ab}{\sqrt {\omega /(e\epsilon _{o}V\hbar )}}}$. The probability that the atom is in state ${\displaystyle |b\rangle }$ at a later time is

<equation id=" vac9" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ P_{b}={\frac {1}{2}}(1+\cos \Omega t).\end{aligned}}}$ </equation>

The frequency ${\displaystyle \Omega }$ is called the vacuum Rabi frequency.

The dynamics of a 2-level atom interacting with a single mode of the vacuum were first analyzed in ^[2] and the oscillations are sometimes called Jaynes-Cummings oscillations.

The atom-vacuum interaction ${\displaystyle H_{FI}^{0}}$, <xr id="vac4"/>, has a simple physical interpretation. The electric field amplitude associated with the zero point energy in the cavity is given by

<equation id=" vac10" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \epsilon _{o}E^{2}V={\frac {1}{2}}\hbar \omega \end{aligned}}}$ </equation>

Consequently, ${\displaystyle |H_{FI}^{0}|=Ed_{ab}=ez_{ab}E}$. The interaction frequency ${\displaystyle |H_{FI}^{0}|/\hbar }$ is sometimes referred to as the vacuum Rabi frequency, although, as we have seen, the actual oscillation frequency is ${\displaystyle 2\times H_{FI}^{0}/\hbar }$.

Absorption and emission are closely related. Because the rates are proportional to ${\displaystyle |\langle F|H_{\rm {int}}|I\rangle |^{2}}$, it is evident from <xr id="vac3"/> that

<equation id=" vac11" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\frac {\rm {Rate~of~emission}}{\rm {Rate~of~absorption}}}={\frac {n+1}{n}}\end{aligned}}}$ </equation>

This result, which applies to radiative transitions between any two states of a system, is general. In the absence of spontaneous emission, the absorption and emission rates are identical.

The oscillatory behavior described by <xr id="vac8"/> is exactly the opposite of free space behavior in which an excited atom irreversibly decays to the lowest available state by spontaneous emission. The distinction is that in free space there are an infinite number of final states available to the photon, since it can go off in any direction, but in the cavity there is only one state. The natural way to regard the atom-cavity system is not in terms of the atom and cavity separately, as in <xr id="vac1"/>, but in terms of the coupled states ${\displaystyle |+\rangle }$ and ${\displaystyle |-\rangle }$ (<xr id="vac5"/>). Such states, called dressed atom states, are the true eigenstates of the atom-cavity system.

Absorption and emission

In Chapter 6, first-order perturbation theory was applied to find the response of a system initially in state ${\displaystyle |a\rangle }$ to a perturbation of the form ${\displaystyle (H_{ba}/2)e^{-i\omega t}}$. The result is that the amplitude for state ${\displaystyle |b\rangle }$ is given by

<equation id=" abem1" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ a_{b}(t)={\frac {1}{2i\hbar }}\int _{0}^{t}H_{ba}e^{-i(\omega -\omega _{ba})t^{\prime }}dt^{\prime }={\frac {H_{ba}}{2\hbar }}{\left[{\frac {e^{-i(\omega -\omega _{ba})t}-1}{\omega -\omega _{ba}}}\right]}\end{aligned}}}$ </equation>

There will be a similar expression involving the time-dependence ${\displaystyle e^{+i\omega t}}$. The ${\displaystyle -i\omega }$ term gives rise to resonance at ${\displaystyle \omega =\omega _{ba}}$; the ${\displaystyle +i\omega }$ term gives rise to resonance at ${\displaystyle \omega =\omega _{ab}}$. One term is responsible for absorption, the other is responsible for emission.

The probability that the system has made a transition to state ${\displaystyle |b\rangle }$ at time ${\displaystyle t}$ is

<equation id=" abem2" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ W_{a\rightarrow b}=|a_{b}(t)|^{2}={\frac {|H_{ba}|^{2}}{4\hbar ^{2}}}{\frac {\sin ^{2}[(\omega -\omega _{ba})t/2]}{((\omega -\omega _{ba})t/2)^{2}}}t^{2}\end{aligned}}}$ </equation>

In the limit ${\displaystyle \omega \rightarrow \omega _{ba}}$, we have

<equation id=" abem3" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ W_{a\rightarrow b}\approx {\frac {|H_{ba}|^{2}}{4\hbar ^{2}}}t^{2}.\end{aligned}}}$ </equation>

So, for short time, ${\displaystyle W_{a\rightarrow b}}$ increases quadratically. This is reminiscent of a Rabi resonance in a 2-level system in the limit of short time.

However, <xr id="abem2"/> is only valid provided ${\displaystyle W_{a\rightarrow b}\ll 1}$, or for time ${\displaystyle T\ll \hbar /H_{ba}}$. For such a short time, the incident radiation will have a spectral width ${\displaystyle \Delta \omega \sim 1/T}$. In this case, we must integrate <xr id="abem2"/> over the spectrum. In doing this, we shall make use of the relation

<equation id=" abem4" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \int _{-\infty }^{+\infty }{\frac {\sin ^{2}(\omega -\omega _{ba})t/2}{[(\omega -\omega _{ba})/2]^{2}}}d\omega =2t\int _{-\infty }^{+\infty }{\frac {\sin ^{2}(u-u_{o})}{(u-u_{o})^{2}}}du\rightarrow 2\pi t\int _{-\infty }^{+\infty }\delta (\omega -\omega _{ba})d\omega .\end{aligned}}}$ </equation>

<xr id="abem2"/> becomes

<equation id=" abem5" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ W_{a\rightarrow b}={\frac {|H_{ba}|^{2}}{\hbar ^{2}}}2\pi t\delta (\omega -\omega _{ba})\end{aligned}}}$ </equation>

The ${\displaystyle \delta }$-function requires that eventually ${\displaystyle W_{a\rightarrow b}}$ be integrated over a spectral distribution function. Absorbing an ${\displaystyle \hbar }$ into the delta function, ${\displaystyle W_{a\rightarrow b}}$ can be written

<equation id=" abem6" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ W_{a\rightarrow b}={\frac {|H_{ba}|^{2}}{\hbar }}2\pi t\delta (E_{b}-E_{a}-\hbar \omega ).\end{aligned}}}$ </equation>

Because the transition probability is proportional to the time, we can define the transition rate

<equation id=" abem7a" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Gamma _{ab}={\frac {d}{dt}}W_{a\rightarrow b}=2\pi {\frac {|H_{ba}|^{2}}{\hbar }}\delta (\omega -\omega _{ba})\end{aligned}}}$ </equation>

<equation id=" abem7b" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ =2\pi {\frac {|H_{ba}|^{2}}{\hbar }}\delta (E_{b}-E_{a}-\hbar \omega )\end{aligned}}}$ </equation>

The ${\displaystyle \delta }$-function arises because of the assumption in first order perturbation theory that the amplitude of the initial state is not affected significantly. This will not be the case, for instance, if a monochromatic radiation field couples the two states, in which case the amplitudes oscillate between 0 and 1. However, the assumption of perfectly monochromatic radiation is in itself unrealistic.

Radiation always has some spectral width. ${\displaystyle |H_{ba}|^{2}}$ is proportional to the intensity of the radiation field at resonance. The intensity can be written in terms of a spectral density function

${\displaystyle {\begin{aligned}S(\omega ^{\prime })=S_{0}f(\omega ^{\prime })\end{aligned}}}$

where ${\displaystyle S_{0}}$ is the incident Poynting vector, and f(${\displaystyle \omega ^{\prime }}$) is a normalized line shape function centered at the frequency ${\displaystyle \omega ^{\prime }}$ which obeys ${\displaystyle \int f(\omega ^{\prime })d\omega ^{\prime }=1}$. We can define a characteristic spectral width of ${\displaystyle f(\omega ^{\prime })}$ by

<equation id=" abem8" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Delta \omega ={\frac {1}{f(\omega _{ab})}}\end{aligned}}}$ </equation>

Integrating <xr id="abem7b"/> over the spectrum of the radiation gives

<equation id=" abem9" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Gamma _{ab}={\frac {2\pi |H_{ba}|^{2}}{\hbar ^{2}}}f(\omega _{ab})\end{aligned}}}$ </equation>

If we define the effective Rabi frequency by

<equation id=" abem10" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Omega _{R}={\frac {|H_{ba}|}{\hbar }}\end{aligned}}}$ </equation>

then

<equation id=" abem11" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Gamma _{ab}={2\pi }{\frac {\Omega _{R}^{2}}{\Delta \omega }}\end{aligned}}}$ </equation>

Another situation that often occurs is when the radiation is monochromatic, but the final state is actually composed of many states spaced close to each other in energy so as to form a continuum. If such is the case, the density of final states can be described by

<equation id=" abem12" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ dN=\rho (E)dE\end{aligned}}}$ </equation>

where ${\displaystyle dN}$ is the number of states in range ${\displaystyle dE}$. Taking ${\displaystyle \hbar \omega =E_{b}-E_{a}}$ in <xr id="abem7b"/>, and integrating gives

<equation id=" abem13" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Gamma _{ab}=2\pi {\frac {|H_{ba}|^{2}}{\hbar ^{2}}}\rho (E_{b})\end{aligned}}}$ </equation>

This result remains valid in the limit ${\displaystyle E_{b}\rightarrow E_{a}}$, where ${\displaystyle \omega \rightarrow 0}$. In this static situation, the result is known as Fermi's Golden Rule .

Note that <xr id="abem9"/> and <xr id="abem13"/> both describe a uniform rate process in which the population of the initial state decreases exponentially in time. If the population of the initial state is ${\displaystyle P(0)}$, then

<equation id=" abem14" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ P(t)=P(0)e^{-\Gamma _{ba}t}\end{aligned}}}$ </equation>

Applying this to the dipole transition described in <xr id="int11"/>, we have

<equation id=" abem15" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Gamma _{ab}=2\pi {\frac {E^{2}d_{ba}^{2}}{\hbar ^{2}}}f(\omega )\end{aligned}}}$ </equation>

The arguments here do not distinguish whether ${\displaystyle E_{a}<E_{b}}$ or ${\displaystyle E_{a}>E_{b}}$ (though the sign of ${\displaystyle \omega =(E_{b}-E_{a})/\hbar }$ obviously does). In the former case the process is absorption, in the latter case it is emission.

Spontaneous emission rate

The rate of absorption, in CGS units, for the transition ${\displaystyle a\rightarrow b}$, where ${\displaystyle E_{b}>E_{a}}$, is, from <xr id="qrd16"/> and <xr id="abem7b"/>,

<equation id=" sem1" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Gamma _{ab}={\frac {4\pi ^{2}}{\hbar V}}|{\bf {\hat {e}}}\cdot {\bf {d}}_{ba}|^{2}n\omega \delta (\omega _{0}-\omega ).\end{aligned}}}$ </equation>

where ${\displaystyle \omega _{0}=(E_{b}-E_{a})/\hbar }$. To evaluate this we need to let ${\displaystyle n\rightarrow n(\omega )}$, where ${\displaystyle n(\omega )d\omega }$ is the number of photons in the frequency interval ${\displaystyle d\omega }$, and integrate over the spectrum. The result is

<equation id=" sem2" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Gamma _{ab}={\frac {4\pi ^{2}}{\hbar V}}|{\bf {\hat {e}}}\cdot {\bf {d}}_{ba}|^{2}\omega _{0}n(\omega _{0})\end{aligned}}}$ </equation>

To calculate ${\displaystyle n(\omega )}$, we first calculate the mode density in space by applying the usual periodic boundary condition

<equation id=" sem3" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ k_{j}L=2\pi n_{j},~~~j=x,y,z.\end{aligned}}}$ </equation>

The number of modes in the range ${\displaystyle d^{3}k=dk_{x}dk_{y}dk_{z}}$ is

<equation id=" sem4" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ dN=dn_{x}dn_{y}dn_{z}={\frac {V}{\left(2\pi \right)^{3}}}d^{3}k={\frac {V}{\left(2\pi \right)^{3}}}k^{2}dk\ d\Omega ={\frac {V}{\left(2\pi \right)^{3}}}{\frac {\omega ^{2}\,d\omega \ d\Omega }{c^{3}}}\end{aligned}}}$ </equation>

Letting ${\displaystyle {\bar {n}}={\bar {n(\omega )}}}$ be the average number of photons per mode, then

<equation id=" sem5" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ n(\omega )={\bar {n}}{\frac {dN}{d\omega }}={\frac {{\bar {n}}V\omega ^{2}d\Omega }{(2\pi )^{3}c^{3}}}\end{aligned}}}$ </equation>

Introducing this into <xr id="sem2"/> gives

<equation id=" sem6" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Gamma _{ab}={\frac {{\bar {n}}\omega ^{3}}{2\pi \hbar c^{3}}}|{\bf {\hat {e}}}\cdot {\bf {d}}_{ba}|^{2}d\Omega \end{aligned}}}$ </equation>

We wish to apply this to the case of isotropic radiation in free space, as, for instance, in a thermal radiation field. We can take ${\displaystyle {\bf {d}}_{ba}}$ to lie along the ${\displaystyle z}$ axis and describe k in spherical coordinates about this axis. Since the wave is transverse, ${\displaystyle {\bf {\hat {e}}}\cdot {\bf {\hat {D}}}=\sin \theta }$ for one polarization, and zero for the other one. Consequently,

<equation id=" sem7" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \int |{\bf {\hat {e}}}\cdot {\bf {d}}_{ba}|^{2}d\Omega =|{\bf {d}}_{ba}|^{2}\int \sin ^{2}\theta d\Omega ={\frac {8\pi }{3}}|{\bf {d}}_{ba}|^{2}\end{aligned}}}$ </equation>

Introducing this into <xr id="sem6"/> yields the absorption rates

<equation id=" sem8" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Gamma _{ab}={\frac {4}{3}}{\frac {\omega ^{3}}{\hbar c^{3}}}|{\bf {d}}_{ba}|^{2}{\bar {n}}\end{aligned}}}$ </equation>

It follows that the emission rate for the transition ${\displaystyle b\rightarrow a}$ is

<equation id=" sem9" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Gamma _{ba}={\frac {4}{3}}{\frac {\omega ^{3}}{\hbar c^{3}}}|{\bf {d}}_{ba}|^{2}({\bar {n}}+1)\end{aligned}}}$ </equation>

If there are no photons present, the emission rate—called the rate of spontaneous emission—is

<equation id=" sem10" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Gamma _{ba}^{0}={\frac {4}{3}}{\frac {\omega ^{3}}{\hbar c^{3}}}|{\bf {d}}_{ba}|^{2}={\frac {4}{3}}{\frac {e^{2}\omega ^{3}}{\hbar c^{3}}}|\langle b|{\bf {r}}|a\rangle |^{2}\end{aligned}}}$ </equation>

In atomic units, in which ${\displaystyle c=1/\alpha }$, we have

<equation id=" sem11" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Gamma _{ba}^{0}={\frac {4}{3}}\alpha ^{3}\omega ^{3}|{\bf {r}}_{ba}|^{2}.\end{aligned}}}$ </equation>

Taking, typically, ${\displaystyle \omega =1}$, and ${\displaystyle r_{ba}=1}$, we have ${\displaystyle \Gamma ^{0}\approx \alpha ^{3}}$. The “${\displaystyle Q}$ of a radiative transition is ${\displaystyle Q=\omega /\Gamma \approx \alpha ^{-3}\approx }$ ${\displaystyle 3\times 10^{6}}$. The ${\displaystyle \alpha ^{3}}$ dependence of ${\displaystyle \Gamma }$ indicates that radiation is fundamentally a weak process: hence the high ${\displaystyle Q}$ and the relatively long radiative lifetime of a state, ${\displaystyle \tau =1/\Gamma }$. For example, for the ${\displaystyle 2P\rightarrow 1S}$ transition in hydrogen (the ${\displaystyle L_{\alpha }}$ transition), we have ${\displaystyle \omega =3/8}$, and taking ${\displaystyle r_{2p,1s}\approx 1}$, we find ${\displaystyle \tau =3.6\times 10^{7}}$ atomic units, or 0.8 ns. The actual lifetime is 1.6 ns.

The lifetime for a strong transition in the optical region is typically 10–100 ns. Because of the ${\displaystyle \omega ^{3}}$ dependence of ${\displaystyle \Gamma ^{0}}$, the radiative lifetime for a transition in the microwave region—for instance an electric dipole rotational transition in a molecule—is longer by the factor ${\displaystyle (\lambda _{\rm {microwave}}/\lambda _{\rm {optical}})^{3}\approx 10^{15}}$, yielding lifetimes on the order of months. Furthermore, if the transition moment is magnetic dipole rather than electric dipole, the lifetime is further increased by a factor of ${\displaystyle \alpha ^{-2}}$, giving a time of thousands of years.

Line Strength

Because the absorption and stimulated emission rates are proportional to the spontaneous emission rate, we shall focus our attention on the Einstein A coefficient:

<equation id=" lines1" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ A_{ba}={\frac {4}{3}}{\frac {e^{2}\omega ^{3}}{\hbar c^{3}}}|\langle b|{\bf {r}}|a\rangle |^{2}\end{aligned}}}$ </equation>

where

<equation id=" lines2" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ |\langle b|{\bf {r}}|a\rangle |^{2}=|\langle b|x|a\rangle |^{2}+|\langle b|y|a\rangle |^{2}+|\langle b|z|a\rangle |^{2}\end{aligned}}}$ </equation>

For an isolated atom, the initial and final states will be eigenstates of total angular momentum. (If there is an accidental degeneracy, as in hydrogen, it is still possible to select angular momentum eigenstates.) If the final angular momentum is ${\displaystyle J_{a}}$, then the atom can decay into each of the ${\displaystyle 2J_{a}+1}$ final states, characterized by the azimuthal quantum number ${\displaystyle m_{a}=-J_{a},-J_{a}+1,\dots ,+J_{a}}$. Consequently,

<equation id=" lines3" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ A_{ba}={\frac {4}{3}}{\frac {e^{2}\omega ^{3}}{\hbar c^{3}}}\sum _{m_{a}}|\langle b,J_{b}|{\bf {r}}|a,J_{a},m_{a}\rangle |^{2}\end{aligned}}}$ </equation>

The upper level, however, is also degenerate, with a (${\displaystyle 2J_{b}+1}$)–fold degeneracy. The lifetime cannot depend on which state the atom happens to be in. This follows from the isotropy of space: ${\displaystyle m_{b}}$ depends on the orientation of ${\displaystyle {\bf {J}}_{b}}$ with respect to some direction in space, but the decay rate for an isolated atom can't depend on how the atom happens to be oriented. Consequently, it is convenient to define the line strength ${\displaystyle S_{ba}}$, given by

<equation id=" lines4" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ S_{ba}=S_{ab}=\sum _{m_{b}}\sum _{m_{a}}|\langle b,J_{b},m_{b}|{\bf {r}}|a,J_{a},m_{a}\rangle |^{2}\end{aligned}}}$ </equation>

Then,

<equation id=" lines5" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ A_{ba}={\frac {4}{3}}{\frac {e^{2}\omega ^{3}}{\hbar c^{3}}}{\frac {S_{ba}}{g_{b}}}={\frac {4}{3}}{\frac {e^{2}\omega ^{3}}{\hbar c^{3}}}{\frac {S_{ba}}{2J_{b}+1}}\end{aligned}}}$ </equation>

The line strength is closely related to the average oscillator strength ${\displaystyle {\bar {f}}_{ab}}$. ${\displaystyle {\bar {f}}_{ab}}$ is obtained by averaging ${\displaystyle f_{ab}}$ over the initial state ${\displaystyle |b\rangle }$, and summing over the values of ${\displaystyle m}$ in the final state, ${\displaystyle |a\rangle }$. For absorption, ${\displaystyle \omega _{ab}>0}$, and

<equation id=" line11" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bar {f}}_{ab}={\frac {2m}{3\hbar }}\omega _{ab}{\frac {1}{2J_{b}+1}}\sum _{m_{b}}\sum _{m_{a}}|\langle b,J_{b},m_{b}|{\bf {r}}|a,J_{a},m_{a}\rangle |^{2}\end{aligned}}}$ </equation>

It follows that

<equation id=" line12" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bar {f}}_{ba}=-{\frac {2J_{b}+1}{2J_{a}+1}}{\bar {f}}_{ab}.\end{aligned}}}$ </equation>

In terms of the oscillator strength, we have

<equation id=" line13" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bar {f}}_{ab}={\frac {2m}{3\hbar }}\omega _{ab}{\frac {1}{2J_{b}+1}}{S}_{ab}.\end{aligned}}}$ </equation>

<equation id=" line14" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bar {f}}_{ba}=-{\frac {2m}{3\hbar }}|\omega _{ab}|{\frac {1}{2J_{a}+1}}{S}_{ab}.\end{aligned}}}$ </equation>

Excitation by narrow and broad band light sources

We have calculated the rate of absorption and emission of an atom in a thermal field, but a more common situation involves interaction with a light beam, either monochromatic or broad band. Here broad band means having a spectral width that is broad compared to the natural line width of the system—the spontaneous decay rate.

For an electric dipole transition, the radiation interaction is

<equation id=" broad1" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ |H_{ba}|=e|{\bf {r}}_{ba}|\cdot {\bf {\hat {e}}}E/2,\end{aligned}}}$ </equation>

where ${\displaystyle E}$ is the amplitude of the field. The transition rate, from <xr id="sem7"/>, is

<equation id=" broad2" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ W_{ab}={\frac {\pi }{2}}{\frac {e^{2}|{\bf {\hat {e}}}\cdot {\bf {r}}_{ba}|^{2}E^{2}}{\hbar ^{2}}}f(\omega _{0})={\frac {\pi }{2}}{\frac {e^{2}|{\bf {\hat {e}}}\cdot {\bf {r}}_{ba}|^{2}E^{2}}{\hbar }}f(E_{b}-E_{a})\end{aligned}}}$ </equation>

where ${\displaystyle \omega _{0}=(E_{b}-E_{a})/\hbar }$ and ${\displaystyle f(\omega )}$ is the normalized line shape function, or alternatively, the normalized density of states, expressed in frequency units. The transition rate is proportional to the intensity ${\displaystyle I_{0}}$ of a monochromatic radiation source. ${\displaystyle I_{0}}$ is given by the Poynting vector, and can be expressed by the electric field as ${\displaystyle E^{2}=8\pi I_{0}/c}$. Consequently,

<equation id=" broad3" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ W_{ab}={\frac {4\pi ^{2}}{c}}{\frac {e^{2}|{\bf {\hat {e}}}\cdot {\bf {r}}_{ba}|^{2}}{\hbar ^{2}}}I_{0}f(\omega _{0})\end{aligned}}}$ </equation>

In the case of a Lorentzian line having a FWHM of ${\displaystyle \Gamma _{0}}$ centered on frequency ${\displaystyle \omega _{0}}$,

<equation id=" broad4" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ f(\omega )={\frac {1}{\pi }}{\frac {(\Gamma _{0}/2)}{(\omega -\omega _{0})^{2}+(\Gamma _{0}/2)^{2}}}\end{aligned}}}$ </equation>

In this case,

<equation id=" broad5" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ W_{ab}={\frac {8\pi e^{2}}{c\hbar ^{2}\Gamma _{0}}}|\langle b|{\bf {\hat {e}}}\cdot {\bf {r}}|a\rangle |^{2}I_{0}\end{aligned}}}$ </equation>

Note that ${\displaystyle W_{ab}}$ is the rate of transition between two particular quantum states, not the total rate between energy levels. Naturally, we also have ${\displaystyle W_{ab}=W_{ba}}$.\

An alternative way to express <xr id="broad2"/> is to introduce the Rabi frequency,

<equation id=" broad6" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \Omega _{R}={\frac {2H_{ba}}{\hbar }}={\frac {e|{\bf {\hat {e}}}\cdot {\bf {r}}_{ba}|E}{\hbar }}\end{aligned}}}$ </equation>

In which case

<equation id=" broad7" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ W_{ab}={\frac {\pi }{2}}\Omega _{R}^{2}f(\omega _{0})=\Omega _{R}^{2}{\frac {1}{\Gamma _{0}}}\end{aligned}}}$ </equation>

If the width of the final state is due soley to spontaneous emission, ${\displaystyle \Gamma _{0}=A=(4e^{2}\omega ^{3}/3\hbar c^{3})|r_{ba}|^{2}}$. Since ${\displaystyle W_{ab}}$ is proportional to ${\displaystyle |r_{ba}|^{2}/A_{0}}$, it is independent of ${\displaystyle |r_{ba}|^{2}}$. It is left as a problem to find the exact relationship, but it can readily be seen that it is of the form

<equation id=" broad8" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ W_{ab}=X\lambda ^{2}I_{0}/\hbar \omega \end{aligned}}}$ </equation>

where X is a numerical factor. ${\displaystyle I/\hbar \omega }$ is the photon flux—i.e. the number of photons per second per unit area in the beam. Since ${\displaystyle W_{ab}}$ is an excitation rate, we interpret ${\displaystyle X\lambda ^{2}}$ as the resonance absorption cross section for the atom, ${\displaystyle \sigma _{0}}$.

At first glance it is puzzling that ${\displaystyle \sigma _{0}}$ does not depend on the structure of the atom; one might expect that a transition with a large oscillator strength—i.e. a large value of ${\displaystyle |r_{ab}|^{2}}$—should have a large absorption cross section. However, the absorption rate is inversely proportional to the linewidth, and since that also increases with ${\displaystyle |r_{ab}|^{2}}$, the two factors cancel out. This behavior is not limited to electric dipole transitions, but is quite general.

There is, however, an important feature of absorption that does depend on the oscillator strength. ${\displaystyle \sigma _{0}}$ is the cross section assuming that the radiation is monochromatic compared to the natural line width. As the spontaneous decay rate becomes smaller and smaller, eventually the natural linewidth becomes narrower than the spectral width of the laser, or whatever source is used. In that case, the excitation becomes broad band.

Broad Band Excitation

We now discuss broad band excitation. Using the result of the last section, finding the excitation rate or the absorption cross section for broad band excitation is trivial. From <xr id="broad2"/>, the absorption rate is proportional to ${\displaystyle f(\omega _{0})}$. For monochromatic excitation, ${\displaystyle f(\omega _{0})=(2/\pi )A^{-1}}$ and ${\displaystyle W_{\rm {mono}}=X\lambda ^{2}I_{0}/\hbar \omega }$. For a spectral source having linewidth ${\displaystyle \Delta \omega _{s}}$, defined so that the normalized line shape function is ${\displaystyle f(\omega _{0})=(2/\pi ){\Delta \omega _{s}}^{-1}}$, then the broad band excitation rate is obtained by replacing ${\displaystyle \Gamma _{0}}$ with ${\displaystyle \Delta \omega _{s}}$ in <xr id="broad8"/>. Thus

<equation id=" band1" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ W_{B}={\left(X\lambda ^{2}{\frac {\Gamma _{0}}{\Delta \omega _{s}}}\right)}{\frac {I_{0}}{\hbar \omega }}\end{aligned}}}$ </equation>

Similarly, the effective absorption cross section is

<equation id=" band2" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \sigma _{\rm {eff}}=\sigma _{0}{\frac {\Gamma _{0}}{\Delta \omega _{s}}}\end{aligned}}}$ </equation>

This relation is valid provided ${\displaystyle \Delta \omega _{s}\gg \Gamma _{0}}$. If the two widths are comparable, the problem needs to be worked out in detail, though the general behavior would be for ${\displaystyle \Delta \omega _{s}\rightarrow (\Delta \omega _{s}^{2}+\Gamma _{0}^{2})^{1/2}}$. Note that ${\displaystyle \Delta \omega _{s}}$ represents the actual resonance width. Thus, if Doppler broadening is the major broadening mechanism then

<equation id=" band3" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \sigma _{\rm {eff}}=\sigma _{0}\Gamma _{0}/\Delta \omega _{\rm {Doppler}}.\end{aligned}}}$ </equation>

Except in the case of high resolution laser spectroscopy, it is generally true that ${\displaystyle \Delta \omega _{s}\gg \Gamma _{0}}$, so that ${\displaystyle \sigma _{\rm {eff}}\ll \sigma _{0}}$.

Saturation and Saturated Absorption Rates

When the external light intensity is strong, the population in the excited state is no longer negligible, and the transition is saturated. We define the saturated absorption rate ${\displaystyle R^{s}}$ as the net transfer from initial state ${\displaystyle a}$ to final state ${\displaystyle b}$, and ${\displaystyle R^{u}}$ is the unsaturated rate for the stimulated absorption and emission,

<equation id=" sat1" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ R^{s}(n_{a}+n_{b})=R^{u}(n_{a}-n_{b}).\end{aligned}}}$ </equation>

When the system reaches steady state,

<equation id=" sat2" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\dot {n_{b}}}&=&-n_{b}(R^{u}+\Gamma )+n_{a}R^{u}=0\\{\dot {n_{a}}}&=&n_{b}(R^{u}+\Gamma )-n_{a}R^{u}=0\\\end{aligned}}}$ </equation>

which gives

<equation id=" sat3" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\frac {n_{b}}{n_{a}}}={\frac {R^{u}}{R^{u}+\Gamma }}\end{aligned}}}$ </equation>

From <xr id="sat1"/>, we have

<equation id=" sat4" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ R^{s}={\frac {\Gamma }{2}}{\frac {S}{1+S}}={\frac {R^{u}}{1+S}}\end{aligned}}}$ </equation>

where ${\displaystyle S}$ is the saturation parameter and is defined as ${\displaystyle S=2R^{u}/\Gamma }$. The transition rate is reduced by a factor of ${\displaystyle 1+S}$ due to saturation.

For low intensity light, ${\displaystyle S\ll 1}$, and ${\displaystyle R^{s}=R^{u}}$; for very high intensity light, ${\displaystyle S\gg 1}$, ${\displaystyle R^{s}=\Gamma /2}$.

For the case of monochromatic radiation, as discussed above, the unsaturated transition rate

<equation id=" sat5" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ R^{u}=W_{ab}={\frac {\pi }{2}}\omega _{R}^{2}f(\omega )={\frac {\omega _{R}^{2}}{\Gamma }}{\frac {1}{1+(2\delta /\Gamma )^{2}}}\end{aligned}}}$ </equation> where ${\displaystyle \delta }$ the detuning with respect to the center frequency ${\displaystyle \omega _{0}}$.

Thus in general the saturated transition rate

<equation id=" sat6" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ R^{s}={\frac {\omega _{R}^{2}}{\Gamma }}{\frac {1}{1+(2\delta /\Gamma )^{2}+2\omega _{R}^{2}/\Gamma ^{2}}}\end{aligned}}}$ </equation> and the saturation parameter <equation id=" sat7" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ S={\frac {S_{res}}{1+(2\delta /\Gamma )^{2}}}\end{aligned}}}$ </equation>

with the resonant saturation parameter ${\displaystyle S_{res}=2\omega _{R}^{2}/\Gamma ^{2}}$.

The saturated rate ${\displaystyle R^{s}}$ has a Lorentzian line with FWHM

<equation id=" sat8" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \delta _{FWHM}={\frac {\Gamma }{2}}{\sqrt {1+S_{res}}}\end{aligned}}}$ </equation>

Power Broadening

This resultant increase in the spectrum width is called saturation (or power) broadening.

The saturation intensity ${\displaystyle I_{sat}}$ is the light field intensity corresponding to the saturation parameter ${\displaystyle S_{res}=1}$ for a resonant light, and that is when ${\displaystyle R^{u}=\omega _{R}^{2}/\Gamma =\Gamma /2}$. Since the Rabi frequency ${\displaystyle \omega _{R}^{2}\propto I}$, we have the linear relation

<equation id=" sat9" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \omega _{R}^{2}={\frac {\Gamma ^{2}}{2}}{\frac {I}{I_{sat}}}\end{aligned}}}$ </equation>

and that gives

<equation id=" sat10" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ I_{sat}={\frac {\Gamma ^{2}}{2}}{\frac {I}{\omega _{R}^{2}}}={\frac {\hbar \omega ^{3}}{12\pi c^{2}}}\Gamma \end{aligned}}}$ </equation> for example, ${\displaystyle I_{sat}=6\;mW/cm^{2}}$ for Na D line.

Saturation Intensity

A quick derivation for the saturation intensity is to express the light intensity ${\displaystyle I}$ and the Rabi frequency ${\displaystyle \omega _{R}}$ in terms of the number of photons ${\displaystyle n}$,

<equation id=" sat11" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ I={\frac {Energy}{Area\times Time}}={\frac {\hbar \omega n}{V/c}}={\frac {\hbar \omega nc}{V}}\end{aligned}}}$ </equation> <equation id=" sat12" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \omega _{R}^{2}=(n+1)\omega _{1}^{2}\simeq n({\vec {d}}\cdot {\hat {e}})^{2}\left({\frac {2}{\hbar }}\right)^{2}\left({\frac {\hbar \omega }{2\epsilon _{0}V}}\right)=n\Gamma {\frac {6\pi c^{3}}{\omega ^{2}V}}\end{aligned}}}$ </equation>

thus <equation id=" sat13" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\frac {I}{\omega _{R}^{2}}}={\frac {\hbar \omega ^{3}}{6\pi c^{2}\Gamma }}\end{aligned}}}$ </equation> and pluging this into <xr id=" sat9"/> gives the saturation intensity.

For the case of broadband radiation, we define the average intensity per frequency interval as ${\displaystyle {\bar {I}}}$, and when the saturation parameter ${\displaystyle S=1}$, ${\displaystyle {\bar {I}}={\bar {I}}_{sat}}$

<equation id=" sat14" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ W_{ge}=B_{ge}{\frac {\bar {I}}{c}}={\frac {\Gamma }{2}}\end{aligned}}}$ </equation> thus

<equation id=" sat15" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bar {I}}_{sat}={\frac {c}{2}}{\frac {A}{B_{ge}}}={\frac {\hbar \omega _{eg}^{3}}{6\pi ^{2}c^{2}}}\end{aligned}}}$ </equation> which is independent of matrix element! For visible light, ${\displaystyle {\bar {I}}_{sat}\approx {\frac {12\;W}{cm^{2}}}{\frac {1}{cm^{-1}}}}$, where ${\displaystyle 1\;cm^{-1}\simeq 30\;GHz}$.

Absorption Cross Section

Cross section is the effective area that represents the probability of some scattering or absorption event. In the case of atom-photon interaction, the absorption rate is the collision rate of an atom with the incoming photons, ${\displaystyle R=n_{phot}\sigma c}$.

For monochromatic radiation,

<equation id=" sat16" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ W_{ge}=n_{phot}\sigma c={\frac {I\sigma }{\hbar \omega }}\end{aligned}}}$ </equation> in the low intensity limit ${\displaystyle W_{ge}=R^{u}}$. If we extrapolate it to saturation parameter ${\displaystyle S=1}$, then ${\displaystyle I=I_{sat}}$, and ${\displaystyle W_{ge}=R^{u}=\Gamma /2}$

<equation id=" sat17" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\frac {\Gamma }{2}}={\frac {I_{sat}\sigma }{\hbar \omega }}\end{aligned}}}$ </equation>

and from <xr id=" sat10"/>, we have

<equation id=" sat18" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \sigma =6\pi {\frac {c^{2}}{\omega ^{2}}}=6\pi (\lambda /2\pi )^{2}\end{aligned}}}$ </equation> This is the resonant cross section for weak radiation, and it is usually much larger than the size of the atom, and independent of matrix element. If we plot the cross section as a function of detuning, it is a Lorentzian line. Strong transitions have a larger widths, but the cross section on resonance is always the same.

When the transition is saturated at high intensity, the resonant cross section goes as ${\displaystyle \sigma =\sigma _{0}/(1+S)}$. The transition bleaches out ${\displaystyle \sigma \rightarrow 0}$ when ${\displaystyle S\gg 1}$.

For broadband radiation,

<equation id=" sat19" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ W_{ge}&=&\int \sigma (\omega ){\frac {{\bar {I}}(\omega )}{\hbar \omega }}d\omega \\&=&{\frac {6\pi (\lambda /2\pi )^{2}}{\hbar \omega _{eg}}}{\bar {I}}(\omega _{eg}){\frac {\pi \Gamma }{2}}\end{aligned}}}$ </equation>

at saturation ${\displaystyle S=1}$,

<equation id=" sat20" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\frac {\Gamma }{2}}={\frac {6\pi (\lambda /2\pi )^{2}}{\hbar \omega _{eg}}}{\bar {I}}_{sat}{\frac {\pi \Gamma }{2}}\end{aligned}}}$ </equation> thus <equation id=" sat21" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bar {I}}_{sat}={\frac {\hbar \omega _{eg}}{6\pi ^{2}(\lambda /2\pi )^{2}}}={\frac {\hbar \omega _{eg}^{3}}{6\pi ^{2}c^{2}}}\end{aligned}}}$ </equation> which is the same as we have derived in <xr id=" sat15"/>.

Higher-order radiation processes

Beyond the dipole approximation: Recall that the interaction Hamiltonian for an atom in an electromagnetic field is given by

<equation id="Hint" noautocaption>(%i) ${\displaystyle {\begin{aligned}H_{\mathrm {int} }=-{\frac {e}{mc}}p\cdot A+{\frac {e^{2}}{2mc^{2}}}|A|^{2}+g_{s}\mu _{B}S\cdot ({\bf {\nabla }}\times A),\end{aligned}}}$ </equation>

where the last term we have so far considered only for static magnetic fields. Neglecting, as before, the ${\displaystyle |A|^{2}}$ term, which is appreciable only for very intense fields, we now consider more fully the dominant term in the atom-field interaction,

<equation id="hor1" noautocaption>(%i) ${\displaystyle {\begin{aligned}H_{ba}={\frac {e}{\rm {mc}}}\langle b|p\cdot A(r)|a\rangle .\end{aligned}}}$ </equation>

For concreteness, we shall take A(r) to be a plane wave of the form

<equation id="hor2" noautocaption>(%i) ${\displaystyle {\begin{aligned}A(r)=A{\hat {z}}e^{ikx}.\end{aligned}}}$ </equation>

Expanding the exponential, we have

<equation id="hor3" noautocaption>(%i) ${\displaystyle {\begin{aligned}H_{ba}={\frac {eA}{\rm {mc}}}\langle b|p_{z}(1+ikx+(ikx)^{2}/2+\dots )|a\rangle .\end{aligned}}}$ </equation>

Thus far in the course, we have considered only the first term, the dipole term. If dipole radiation is forbidden, for instance if ${\displaystyle |a\rangle }$ and ${\displaystyle |b\rangle }$ have the same parity, then the second term in the parentheses becomes important. Usually, it is ${\displaystyle \alpha }$ times smaller. In particular, since

<equation id="hor4" noautocaption>(%i) ${\displaystyle {\begin{aligned}kr\approx {\frac {\hbar \omega }{\hbar c}}a_{0}\approx {\frac {e^{2}/a_{0}}{\hbar c}}a_{0}\approx {\frac {e^{2}}{\hbar c}}=\alpha ,\end{aligned}}}$ </equation>

the expansion in <xr id = "hor3"/> is effectively an expansion in ${\displaystyle \alpha }$. We can rewrite the second term as follows:

<equation id="hor5" noautocaption>(%i) ${\displaystyle {\begin{aligned}p_{z}x=(p_{z}x-zp_{x})/2+(p_{z}x+zp_{x})/2.\end{aligned}}}$ </equation>

The first term of <xr id="hor4"/> is ${\displaystyle -\hbar L_{y}/2}$, and the matrix element becomes

<equation id="hor6" noautocaption>(%i) ${\displaystyle {\begin{aligned}-{\frac {ieAk}{2m}}\langle b|\hbar L_{y}|a\rangle =-iAk\langle b|\mu _{B}L_{y}|a\rangle ,\end{aligned}}}$ </equation>

where ${\displaystyle \mu _{B}=e\hbar /2m}$ is the Bohr magneton. The magnetic field is ${\displaystyle B=-ikA{\hat {y}}}$. Consequently, <xr id="hor5"/> can be written in the more familiar form ${\displaystyle -{\vec {\mu }}\cdot B}$. (The orbital magnetic moment is ${\displaystyle {\vec {\mu }}=-\mu _{B}L}$: the minus sign arises from our convention that ${\displaystyle e}$ is positive.) We can readily generalize the matrix element to

<equation id="hor7" noautocaption>(%i) ${\displaystyle {\begin{aligned}H_{\rm {int}}(M1)=B\cdot \mu _{B}\langle b|L+g_{s}S|a\rangle ,\end{aligned}}}$ </equation>

where we have added the spin dependent term from <xr id="Hint"/>. ${\displaystyle M1}$ indicates that the matrix element is for a magnetic dipole transition. The strength of the ${\displaystyle M1}$ transition is set by

<equation id="hor8" noautocaption>(%i) ${\displaystyle {\begin{aligned}\mu _{B}/c={\frac {1}{2}}{\frac {e\hbar }{mc}}={\frac {1}{2}}{\frac {e^{2}}{\hbar c}}{\frac {\hbar ^{2}}{em}}={\frac {1}{2}}\alpha ea_{0},\end{aligned}}}$ </equation>

so it is indeed a factor of ${\displaystyle \alpha }$ weaker than a dipole transition, as we argued above.

The second term in <xr id ="hor4"/> involves ${\displaystyle (p_{z}x+zp_{x})/2}$. Making use of the commutator relation ${\displaystyle [r,H_{0}]=i\hbar p/m}$, we have

<equation id="hor9" noautocaption>(%i) ${\displaystyle {\begin{aligned}{\frac {1}{2}}(p_{z}x+zp_{x})={\frac {m}{2i\hbar }}([z,H_{0}]x+z[x,H_{0}])={\frac {m}{2i\hbar }}(-H_{0}zx+zxH_{0}).\end{aligned}}}$ </equation>

So, the contribution of this term to ${\displaystyle H_{ba}}$ is

<equation id="hor10" noautocaption>(%i) ${\displaystyle {\begin{aligned}{\frac {ieA}{mc}}{\frac {km}{2\hbar i}}\langle b|-H_{0}zx+zxH_{0}|a\rangle =-{\frac {eAk}{2c}}{\frac {E_{b}-E_{a}}{\hbar }}\langle b|zx|a\rangle ={\frac {ieE\omega }{2c}}\langle b|zx|a\rangle ,\end{aligned}}}$ </equation>

where we have taken ${\displaystyle E=ikA}$. This is an electric quadrupole interaction, and we shall denote the matrix element by

<equation id="hor11" noautocaption>(%i) ${\displaystyle {\begin{aligned}H_{\rm {int}}(E2)^{\prime }={\frac {ie\omega }{2c}}\langle b|zx|a\rangle E.\end{aligned}}}$ </equation>

The prime indicates that we are considering only one component of a more general expression involving the matrix element ${\displaystyle \langle b|r:r|a\rangle }$ of a tensor product. It is straightforward to verify that the electric quadrupole interaction is also of order ${\displaystyle \alpha }$.

The total matrix element of the second term in the expansion of <xr id="hor3"/> can be written

<equation id="hor12" noautocaption>(%i) ${\displaystyle {\begin{aligned}H_{\rm {int}}^{(2)}=H_{\rm {int}}(M1)+H_{\rm {int}}(E2).\end{aligned}}}$ </equation>

Note that ${\displaystyle H_{\rm {int}}(M1)}$ is real, whereas ${\displaystyle H_{\rm {int}}(E2)}$ is imaginary. Consequently,

<equation id="hor13" noautocaption>(%i) ${\displaystyle {\begin{aligned}|H_{\rm {int}}^{(2)}|^{2}=|H_{\rm {int}}(M1)|^{2}+|H_{\rm {int}}(E2)|^{2}.\end{aligned}}}$ </equation>

The magnetic dipole and electric quadrupole terms do not interfere.

Because transition rates depend on ${\displaystyle |H_{ba}|^{2}}$, the magnetic dipole and electric quadrupole rates are both smaller than the dipole rate by ${\displaystyle \alpha ^{2}\sim 5\times 10^{-5}}$. For this reason they are generally referred to as forbidden processes. However, the term is used somewhat loosely, for there are transitions which are much more strongly suppressed due to other selection rules, as for instance triplet to singlet transitions in helium.

Summary of dipole and higher-order radiation processes.

Transition		Operator	Parity
Electric Dipole	${\displaystyle E1}$	${\displaystyle -er}$	-
Magnetic Dipole	${\displaystyle M1}$	${\displaystyle -\mu _{B}(L+g_{s}S)}$	+
Electric Quadrupole	${\displaystyle E2}$	${\displaystyle -er:r}$	+

Selection rules

A forbidden transition, then, is one that is weaker than an electric dipole-allowed transition by ${\displaystyle \alpha ^{n}}$ and only appears in some higher-order approximation. Examples of such higher-order effects are the magnetic dipole and electric quadrupole terms described above, multiphoton processes, the relativistic effects which allow singlet to triplet transitions in helium, and hyperfine interactions within the nucleus. To derive selection rules for the transitions we have discussed above, it is useful to express the matrix elements in terms of spherical tensor operators:

${\displaystyle H_{int}(T_{l,m})=\langle nJM|T_{l,m}|n'J'M'\rangle ,}$

where ${\displaystyle T_{l,m}}$ is a spherical tensor operator of rank ${\displaystyle l}$. The operators ${\displaystyle T_{l,m}}$ transform under rotations like the spherical harmonics ${\displaystyle Y_{l,m}}$, and any operator can be written as a linear combination of these spherical tensors. By the Wigner-Eckart Theorem, we can express the matrix element

${\displaystyle \langle nJM|T_{l,m}|n'J'M'\rangle ={\frac {\langle nJ\|T_{l}\|n'J'\rangle }{\sqrt {2J+1}}}\langle J'l,M',m|JM\rangle }$

in terms of a reduced matrix element ${\displaystyle \langle nJ\|T_{l}\|n'J'\rangle }$ and a Clebsch-Gordan coefficient ${\displaystyle \langle J'l,M',m|JM\rangle }$. In order for the latter to be nonzero, the triangle rule requires that ${\displaystyle |J'-J|\leq l\leq |J'+J|}$, while conservation of angular momentum requires ${\displaystyle M=M'+m}$. Since the operators ${\displaystyle er}$ and ${\displaystyle \mu _{B}B}$ responsible for ${\displaystyle E1}$ and ${\displaystyle M1}$ transitions are both vectors, i.e. tensors of rank ${\displaystyle l=1}$, these transitions are both governed by the dipole selection rules

${\displaystyle {\begin{aligned}|\Delta J|&=0,1;\\|\Delta m|&=0,1.\end{aligned}}}$

Since ${\displaystyle {\bf {r}}}$ is a polar vector and ${\displaystyle {\bf {L}}}$ is an axial vector, ${\displaystyle E1}$ transitions are allowed only between states of opposite parity and ${\displaystyle M}$ transitions are allowed only between states of the same parity. The operator responsible for ${\displaystyle E2}$ transitions is a spherical tensor of rank 2. For example,

${\displaystyle xz=(T_{2,-1}-T_{2,1})/4.}$

In general, then, we expect that the quadrupole moment can be expressed in terms of ${\displaystyle T_{2,M}({\bf {r}})}$. Thus, electric quadrupole transitions are allowed only between states connected by tensors ${\displaystyle T_{2,m}(r)}$, requiring:

${\displaystyle {\begin{aligned}|\Delta J|&=0,1,2;\\|\Delta m|&=0,1,2.\end{aligned}}}$

and parity unchanged.

In addition, ${\displaystyle J=0\rightarrow J'=0}$ transitions are forbidden in all of the cases considered above, since ${\displaystyle J=J'=0}$ requires ${\displaystyle \Delta L=0}$ (for any interaction that does not couple to spin) whereas absorption or emission of a photon implies ${\displaystyle |\Delta L|=1}$.

We now illustrate the use of the spherical tensor for the case of a vector. The dipole matrix element for a particular polarization of the field, ${\displaystyle {\hat {\bf {e}}}}$, is

<equation id=" select1" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ {\bf {\hat {e}}}\cdot {\bf {r}}_{ba}={\bf {\hat {e}}}\cdot \langle b,J_{b},m_{b}|{\bf {r}}|a,J_{a},m_{a}\rangle .\end{aligned}}}$ </equation>

It is straightforward to calculate ${\displaystyle x_{ba},y_{ba},z_{ba},}$ but a more general approach is to write r in terms of a spherical tensor. This yields the selection rules directly, and allows the matrix element to be calculated for various geometries using the Wigner-Eckart theorem as discussed above.

The orbital angular momentum operator of a system with total angular momentum ${\displaystyle L}$ can be written in terms of a spherical harmonic ${\displaystyle Y_{L,M}}$. Consequently, the spherical harmonics constitute spherical tensor operators. A vector can be written in terms of spherical harmonics of rank 1. This permits the vector operator r to be expressed in terms of the spherical tensor ${\displaystyle T_{1,M}({\bf {r}}).}$

The spherical harmonics of rank 1 are

<equation id=" select2" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ Y_{1,0}={\sqrt {\frac {3}{4\pi }}}\cos \theta ;\qquad Y_{1,+1}=-{\sqrt {\frac {3}{8\pi }}}\sin \theta e^{+i\phi }\qquad Y_{1,-1}={\sqrt {\frac {3}{8\pi }}}\sin \theta e^{-i\phi }\end{aligned}}}$ </equation>

These are normalized so that

<equation id=" select3" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \int Y_{1,m^{\prime }}^{*}Y_{1,m}\sin \theta d\theta d\phi =\delta _{m^{\prime },m}\end{aligned}}}$ </equation>

We can write the vector r in terms of components ${\displaystyle r_{m},\ m=+1,0,-1}$,

<equation id=" select4" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ r_{0}=r{\sqrt {\frac {4\pi }{3}}}Y_{1,0},\qquad r_{\pm }=r{\sqrt {\frac {4\pi }{3}}}Y_{1,\pm 1},\end{aligned}}}$ </equation>

or, more generally

<equation id=" select5" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ r_{M}=rT_{1,M}(\theta ,\phi )\end{aligned}}}$ </equation>

Consequently,

<equation id=" select6" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ \langle b,J_{b},m_{b}|r_{M}|a,J_{a},m_{a}\rangle =\langle b,J_{b},m_{b}|rT_{1,M}|a,J_{a},m_{a}\rangle \end{aligned}}}$ </equation>

<equation id=" select7" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ =\langle b,J_{b}|r|a,J_{a}\rangle \langle J_{b},m_{b}|T_{1,M}|J_{a},m_{a}\rangle \end{aligned}}}$ </equation>

The first factor is independent of ${\displaystyle m}$. It is

<equation id=" select8" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ r_{ba}=\int _{0}^{\infty }R_{b,J_{b}}^{*}(r)rR_{a,J_{a}}(r)r^{2}dr\end{aligned}}}$ </equation>

where ${\displaystyle r_{ba}}$ contains the radial part of the matrix element. It vanishes unless ${\displaystyle |b\rangle }$ and ${\displaystyle |a\rangle }$ have opposite parity. The second factor in <xr id="select7"/> yields the selection rule

<equation id=" select9" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ |J_{b}-J_{a}|=0,1;~~~m_{b}=m_{a}\pm M=m_{a},m_{a}\pm 1\end{aligned}}}$ </equation>

Similarly, for magnetic dipole transition, <xr id="hor6"/>, we have

<equation id=" select10" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ H_{ba}(M1)=\mu _{B}B\langle b,J_{b},m_{b},|T_{LM}(L)|a,J_{a},m_{a}\rangle \end{aligned}}}$ </equation>

It immediately follows that parity is unchanged, and that

<equation id=" select11" noautocaption>(%i) ${\displaystyle {\begin{aligned}\ |\Delta J|=0,1~~~(J=0\rightarrow J=0~{\mbox{forbidden}});~~|\Delta m|=0,1\end{aligned}}}$ </equation>

This discussion of matrix elements, selection rules, and radiative processes barely skims the subject. For an authoritative treatment, the books by Shore and Manzel, and Sobelman are recommended.

References

JAC63 E.T. Jaynes and F.W. Cummings, Proc. IEEE, 51, 89 (1963).

EIN17 A. Einstein, Z. Phys. 18, 121 (1917), reprinted in English by D. ter Haar, The Old Quantum Theory, Pergammon, Oxford.

EIN17a A. Einstein, Z. Phys. 18, 121 (1917), translated in Sources of Quantum Mechanics, B. L. Van der Waerden, Cover Publication, Inc., New York, 1967. This book is a gold mine for anyone interested in the development of quantum mechanics.