Difference between revisions of "Coherence"

Introduction

In atomic physics, the term coherence is thrown around in many different contexts, and is often the cause of much confusion. Generally speaking, we say “a system is coherent”, when there exists a definite, non-random phase relationship between two or more eigenstates in the system. Coherence in a system typically leads to interference effects, which is the result of the defined phases in a system adding up constructively or destructively when calculating probability amplitudes, i.e. ${\displaystyle |\langle \phi |\psi \rangle |^{2}}$.

A loss of coherence (i.e. loss of the knowledge of the phases in a system) occurs when the system is coupled to an uncontrolled environment. Thus, to experimentally create a coherent system usually requires that the coupling to the uncontrolled environment be made negligible. For example, in a two level system, coherent Rabi oscillations are visible when the Rabi frequency is much greater than the spontaneous emission rate, i.e. ${\displaystyle \Omega _{\text{Rabi}}\gg \Gamma }$. One can achieve this by using a system with naturally low coupling to the environment (e.g. a narrow linewidth transition, such as magnetic dipole transitions in precessing spins), or a very strong coupling ${\displaystyle \Omega _{\text{Rabi}}}$ (e.g. a strong laser).

Here, we explore many examples where coherence and interference play an important role.

Spontaneous Emission

The coherence of a system is gradually destroyed by so-called spontaneous processes. What is spontaneous emission?

Question: Spontaneous emission...

A is a unitary time evolution of the wave function of the total system

B introduces a random phase into the time evolution of the quantum system

Answer: the total system evolves by ${\displaystyle \sum _{\text{modes}}{\frac {\omega _{R}}{2}}(\sigma ^{+}a+\sigma ^{-}a^{+})}$, hence is it unitary (i.e. energy conserving)

Question: The randomness of spontaneous emission occurs...

A in the measurement process of the photon

B by performing a partial trace over the states of the photon

C both A or B is possible

Answer: how do we measure a photon?

Coherence in two-level systems

Measuring Coherence

A two-level atom can be prepared by a ${\displaystyle \pi /2}$ pulse in a superposition ${\displaystyle 1/{\sqrt {2}}(|g\rangle +e^{-i\phi _{0}}|e\rangle )\otimes |0\rangle }$, where ${\displaystyle |0\rangle }$ is the quantum state of the photon field after excitation. This total quantum state of the atom and photon field can be viewed as exhibiting coherence, since the initial phase ${\displaystyle \phi _{0}}$ between ${\displaystyle |e\rangle }$ and ${\displaystyle |g\rangle }$ is well defined, and the system will evolve coherently as ${\displaystyle 1/{\sqrt {2}}(|g\rangle +e^{-i(\omega _{o}t+\phi _{0})}|e\rangle )\otimes |0\rangle }$. This occurs for times ${\displaystyle t\leq \ 1/\omega _{1}}$, where ${\displaystyle \omega _{1}}$ is the vacuum Rabi oscillation frequency, after which ${\displaystyle |e\rangle \otimes |0\rangle \longrightarrow |g\rangle \otimes |1\rangle }$. After this "spontaneous emission" has occurred the state of the system is ${\displaystyle |g\rangle \otimes (1/{\sqrt {2}}(|0\rangle +e^{-i(\omega _{o}t+\phi _{0})}|1\rangle )}$, and the quantum state of the atom has been mapped onto the photon field. The figure below displays a conceptual experiment that can be used to test this, where an interferometer is used to perform an optical homodyne detection of the light emitted by the atom and thereby obtain its phase (relative to that of the excitation light).

Measurement of definite phase for light emitted by a two-level atom prepared with a ${\displaystyle \pi /2}$ pulse. The laser light is sent through both arms of an interferometer; a switch in one arm selects a ${\displaystyle \pi /2}$ pulse of light from the laser with which to excite the atom. The light emitted by the atomic dipole as a result is then mixed with the other interferometer arm at the output. Averaging the output signal over many repetitions of the experiment, the interferometer measures a definite phase for the light emitted by the atom, defined relative to the phase of the exciting ${\displaystyle \pi /2}$ pulse.

What about an atom prepared by a ${\displaystyle \pi }$ pulse in ${\displaystyle |e\rangle }$? There is no coherence at ${\displaystyle t=0}$, since the atom is in a single state, but what about ${\displaystyle t=1/(\omega _{1}/2)}$? Then the atom is in a superposition of states ${\displaystyle \sim |g\rangle +e^{-i\omega _{0}t+\phi _{0}}|e\rangle }$. Obviously some phase must exist, because otherwise no dipole moment ${\displaystyle {\bf {d}}(t)=\langle e(t)|q{\bf {r}}|g(t)\rangle }$ exists that can emit, but the phase ${\displaystyle \phi _{0}}$ is completely unpredictable, so the experiment pictured above would yield no definite phase. Indeed the measurement would be an ensemble average over all possible phases (${\displaystyle \int _{0}^{2\pi }d\phi \langle e|e^{i\phi }q{\bf {r}}|g\rangle =0}$). We conclude that an atom prepared in ${\displaystyle |e\rangle }$ does not exhibit coherence.

Ensemble average of the phase measurement.

The ensemble average as in the figure above (parallel setups) or time average (repeated experiment at same location) yields no definite phase, so we conclude that the expectation value of the dipole moment ${\displaystyle \langle d(t)\rangle =0}$ is zero at all times (but ${\displaystyle \langle d^{2}\rangle \neq 0}$!). What is the origin of this uncertain phase ${\displaystyle \phi _{o}}$? The answer is vacuum fluctuations.

What then happens if we place two atoms close together and excite them at the same time? Is the relative phase of the evolving dipole moments fixed or uncertain? If the relative phase is fixed, how close must the atoms be for the relative phase to be well defined? These questions about spatial coherence and Dicke superradiance will be covered later in this chapter.

More on the coherence of atoms and light

Consider the coherence of an atom after coherent excitation with a short pulse (shorter than emission rate). Let the state of the atom be ${\displaystyle |\psi \rangle =C_{g}|g\rangle +C_{e}|e\rangle }$. Then, the coherence between ${\displaystyle |e\rangle }$ and ${\displaystyle |g\rangle }$ is maximum for ${\displaystyle C_{e}=C_{g}=1/{\sqrt {2}}}$, i.e. with a ${\displaystyle \pi /2}$ pulse. Indeed, recall that the coherences are the off-diagonal elements of the density matrix, ${\displaystyle \rho _{ab}}$. For a pure state, they are ${\displaystyle C_{g}C_{e}^{*}}$ and c.c..

Now, let us consider a system with an atom and a single EM mode (as for example an atom strongly coupled to a cavity). Then, emission couples atomic states with photon number states: ${\displaystyle |g,1\rangle }$ and ${\displaystyle |e,0\rangle }$. Thus, a ${\displaystyle \pi /2}$ pulse also maximizes the coherence ${\displaystyle |g,1\rangle }$ and ${\displaystyle |e,0\rangle }$.

Similarly, consider a coherent light which is very weak. Monochromatic, coherent light is represented by a coherent state${\displaystyle |\alpha >}$ that has a Poissonian distribution of photon numbers:

${\displaystyle |\alpha \rangle =e^{-{\frac {1}{2}}|\alpha |^{2}}\sum _{n=0}^{\infty }{\frac {\alpha ^{n}}{\sqrt {n+1}}}|n\rangle }$

For ${\displaystyle |\alpha |\ll 1}$, the population of the states with ${\displaystyle n>1}$ is negligible, and the atom prepared in a state ${\displaystyle |g>+\epsilon |e>}$ with ${\displaystyle |\epsilon |\ll 1}$ emits a coherent state of light, in agreement with what is expected for small saturation (see the Dressed Atom section).

On the other hand, for continuous excitation (not a short pulse), saturation of the atom leads to emission of increasingly incoherent light (see Mollow triplet, or Cohen-Tannoudji p:424).

Precession of a spin in a magnetic field

Precession of a spin can be viewed as an effect of coherence since ${\displaystyle |x\rangle =1/{\sqrt {2}}(|+z\rangle +|-z\rangle )}$. In a magnetic field (see earlier section), ${\displaystyle |\psi (t)\rangle =1/{\sqrt {2}}(e^{-i\omega _{L}{\frac {t}{2}}}|+z\rangle +e^{i\omega _{L}{\frac {t}{2}}}|-z\rangle )}$, corresponding to precession in the x-y plane. In other words, the precession is due to a coherence between the ${\displaystyle |\pm z\rangle }$ components of the spin. If no coherence existed, the spin would be in a statistical mixture of ${\displaystyle |+z\rangle }$ and ${\displaystyle |-z\rangle }$, exhibiting no measurable precession. In the density matrix formalism,

${\displaystyle \rho =|\psi (t)\rangle \langle \psi (t)|=\left({\begin{array}{cc}{\frac {1}{2}}&{\frac {1}{2}}e^{-i\omega _{L}t}\\{\frac {1}{2}}e^{i\omega _{L}t}&{\frac {1}{2}}\\\end{array}}\right)}$

in the z basis ${\displaystyle |+z\rangle =\left({\begin{array}{cc}1\\0\end{array}}\right),|-z\rangle =\left({\begin{array}{cc}0\\1\end{array}}\right)}$.

The expectation value of ${\displaystyle {\hat {\sigma }}_{x}=\left({\begin{array}{cc}0&1\\1&0\end{array}}\right)}$ is

${\displaystyle \langle {\hat {\sigma }}_{x}\rangle =Tr[\rho {\hat {\sigma }}_{x}]=Tr\left({\begin{array}{cc}{\frac {1}{2}}e^{-i\omega _{L}t}&{\frac {1}{2}}\\{\frac {1}{2}}&{\frac {1}{2}}e^{i\omega _{L}t}\end{array}}\right)=\cos \omega _{L}t.}$

If the coherences (off-diagonal elements of ${\displaystyle {\hat {\rho }}}$) were smaller, ${\displaystyle \langle {\hat {\sigma }}_{x}\rangle }$ would be smaller. For a statistical mixture of ${\displaystyle |+z\rangle }$ and ${\displaystyle |-z\rangle }$, ${\displaystyle \rho =\left({\begin{array}{cc}{\frac {1}{2}}&0\\0&{\frac {1}{2}}\end{array}}\right)}$ and ${\displaystyle \langle {\hat {\sigma }}_{x}\rangle =0}$.

The Stern-Gerlach experiment and (ir)reversible spatial loss of coherence

Stern-Gerlach experiment. Where, in the magnet or outside, does the projection onto ${\displaystyle |\pm z\rangle }$ occur?

Spatial wave function and corresponding spin density matrix in the Stern-Gerlach experiment.

In the Stern-Gerlach experiment a particle initially spin-polarized along ${\displaystyle |x\rangle }$ has equal probability of following either the ${\displaystyle |+z\rangle }$ trajectory or the ${\displaystyle |-z\rangle }$ trajectory. So initially the particle is described by a density matrix for a pure state,

${\displaystyle \rho _{in}=|\chi \rangle \langle \chi |=\left({\begin{array}{cc}{\frac {1}{2}}&{\frac {1}{2}}\\{\frac {1}{2}}&{\frac {1}{2}}\end{array}}\right),}$

after passing the Stern-Gerlach apparatus (inhomogeneous magnetic field) the density matrix is

${\displaystyle \rho _{out}=\left({\begin{array}{cc}{\frac {1}{2}}&0\\0&{\frac {1}{2}}\end{array}}\right)}$

with no interference possible between the two states. Why? Because describing the full quantum state of the particle also requires accounting for its spatial wavefunction. The density matrix above does not contain all the relevant degrees of freedom. Correctly, the particle should initially be described by

${\displaystyle |\psi \rangle =|x\rangle \otimes |\psi _{\text{spatial}}\rangle ={\frac {1}{\sqrt {2}}}\left({\begin{array}{c}\psi _{in}({\bf {r}})\\\psi _{in}({\bf {r}})\end{array}}\right)}$

with ${\displaystyle \psi _{+z}({\bf {r}})=\psi _{-z}({\bf {r}})=\psi _{in}({\bf {r}})}$, i.e. a spatial wavefunction independent of internal state, ${\displaystyle \rho _{in}=\rho _{in,spin}\otimes \rho _{in,spatial}}$. In the inhomogeneous magnetic field, the wavefuntion components ${\displaystyle \psi _{+z},\psi _{-z}}$ evolve differently because there is a different potential energy seen by the two spin states ${\displaystyle |\pm z\rangle }$:

${\displaystyle |\psi (t)\rangle ={\frac {1}{\sqrt {2}}}\left({\begin{array}{c}\psi _{+z}({\bf {r}},t)\\\psi _{-z}({\bf {r}},t)\end{array}}\right).}$

Using the density matrix formalism:

${\displaystyle \rho (t)=|\psi (t)\rangle \langle \psi (t)|={\frac {1}{2}}\left({\begin{array}{cc}|\psi _{+z}({\bf {r}},t)|^{2}&\psi _{+z}^{\dagger }({\bf {r}},t)\psi _{-z}({\bf {r}},t)\\\ \psi _{+z}({\bf {r}},t)\psi _{-z}^{\dagger }({\bf {r}},t)&|\psi _{-z}({\bf {r}},t)|^{2}\end{array}}\right)}$

And so the spin coherence as earlier defined is simply:

${\displaystyle \langle {\hat {\sigma }}_{x}\rangle =Tr(\rho (t){\hat {\sigma }}_{x})=\int d{\bf {{r}{\frac {1}{2}}(\psi _{+z}^{\dagger }({\bf {r}},t)\psi _{-z}({\bf {r}},t)+\psi _{+z}({\bf {r}},t)\psi _{-z}^{\dagger }({\bf {r}},t))}}}$

Which is indeed zero in the absence of spatial overlap of the ${\displaystyle |\pm z\rangle }$ components.

The coherence (interference) between ${\displaystyle |+z\rangle }$ and ${\displaystyle |-z\rangle }$ components to form ${\displaystyle |x\rangle }$ thus exists only in the region where there is at least partial overlap between the two wavefunctions ${\displaystyle \psi _{+z}({\bf {r}}),\psi _{-z}({\bf {r}})}$. When the wavefunctions do not overlap, there is no significance to a relative phase between ${\displaystyle |+z\rangle }$ and ${\displaystyle |-z\rangle }$, i.e. no interference term. (Of course, if the wavefunctions are steered back to overlap, we can ask if there was a well-defined relative phase between them while they were separated.) In a more complete description, the inhomogeneous magnetic field entangles the spatial and spin degrees of freedom. When the spatial overlap disappears, or equivalently, when we trace over the spatial wavefunction (by measuring the particle either at location 1 or at location 2), the interference between ${\displaystyle |+z\rangle }$ and ${\displaystyle |-z\rangle }$ giving rise to ${\displaystyle |x\rangle }$ disappears. In a measurement language, the inhomogeneous magnetic field entangles the "variable" (${\displaystyle |\pm z\rangle }$) with the "meter" (the spatial wavefunctions of the particle). Once the spatial wavefunctions ${\displaystyle \psi _{+z}({\bf {r}}),\psi _{-z}({\bf {r}})}$ cease to overlap, the particle's position can serve as a "meter" for the variable to be measured, the spin along ${\displaystyle \pm z}$. However, until the particle hits the screen, or is subjected to uncontrolled or unknown magnetic fields, the meter-variable entanglement is still reversible, and a "measurement" has not been made.

Quantum Beats

Quantum Beat Levels Multiple levels within energy ${\displaystyle \hbar \Delta }$ from ground state, ${\displaystyle \Delta >\Gamma ,\Gamma ',\Gamma '',\ldots }$.

Quantum beats can be thought of as a two-level effect, though they are observed in multilevel atoms. They allow one to measure level spacings with high resolution when a narrowband excitation source (narrowband laser) is not available.

Consider the scenario of the figure on the right (Quantum Beat Levels), where we have multiple excited levels in a narrow energy interval ${\displaystyle \hbar \Delta }$, all decaying to a common ground state. If we excite with a pulse of duration ${\displaystyle \Delta t\ll 1/\Delta }$ (or a broadband source), we cannot resolve the levels, and they will be populated according to the coupling strength to the ground state ${\displaystyle |g\rangle }$ for the given excitation method:

${\displaystyle |\psi (0)\rangle =\Sigma c_{i}|e^{(i)}\rangle }$

and for times ${\displaystyle t\ll {\frac {1}{\Gamma }},{\frac {1}{\Gamma '}},{\frac {1}{\Gamma ''}},\ldots }$, the state vector is

${\displaystyle |\psi (t)\rangle =\Sigma c_{i}e^{-i\omega _{i}t}|e^{(i)}\rangle .}$

It follows that, in directions where the radiation from levels ${\displaystyle |e^{(i)}\rangle }$ and ${\displaystyle |e^{(j)}\rangle }$ interferes, there will be oscillating terms at frequencies ${\displaystyle \omega _{i}-\omega _{j}}$ on top of the excited state decay, i.e. the so-called "quantum beats".

This allows one to measure excited-state splittings in spite of the lack of a sufficiently narrow excitation source. Compared to our initial example of a two-level atom, here the coherence is initially purely between the excited states (definite excitation phase between them, i.e. see ${\displaystyle |\psi (t)\rangle }$ above ), while no coherence between ${\displaystyle |e^{(i)}\rangle }$ and ${\displaystyle |g\rangle }$ exists initially. Of course, as the atom decays, coherences between ${\displaystyle |e^{(i)}\rangle }$ and ${\displaystyle |g\rangle }$ (e.g. dipole moments) build up, and the coherence between the emitted fields of the different dipoles gives rise to the observed effect. The two following figures show respectively an idealized quantum beat signal and real data from an experimental demonstration of the technique.

Idealized quantum beat signal.

Schematic level diagrams and observed quantum beats of ${\displaystyle ^{4}He3^{3}P}$ at 475 keV/atom; H, n=3, and H, n=4 at 133 keV/atom. \cite{Andra1970}

Delayed Detection

Suppose we prepare a system at ${\displaystyle t=0}$, but only start detection after a time ${\displaystyle t_{0}\gg 1/\Gamma }$, can one obtain a spectral resolution narrower than ${\displaystyle \Gamma }$?

Our signal is:

${\displaystyle S(t)=(1+\alpha \cos(\omega _{0}t))e^{-\Gamma t}}$,

whose Fourier Transform is a Lorentzian

${\displaystyle L(x)={\frac {1}{1+x^{2}}}}$,

where ${\displaystyle x={\frac {\omega -\omega _{0}}{\Gamma }}}$.

Starting the measurement at ${\displaystyle t_{0}}$ is equivalent to the spectrum:

${\displaystyle S_{0}(\omega )=\int _{t_{0}}^{\infty }S(t)e^{-i\omega t}dt}$

Let ${\displaystyle T=t_{0}\Gamma }$, then:

${\displaystyle \Re (S_{0}(\omega ))=F(x)=L(x)e^{-T}(\cos(xT)-x\sin(xT))}$

${\displaystyle \Im (S_{0}(\omega ))=G(x)=L(x)e^{-T}(\sin(xT)-x\cos(xT))}$

Of course if the absolute magnitude of the spectrum is considered, the Lorentzian part is independent of ${\displaystyle T}$:

${\displaystyle |F(x)+iG(x)|^{2}=F(x)^{2}+G(x)^{2}=e^{-2T}L(x)}$

However ${\displaystyle F(x)}$ at large ${\displaystyle x}$ has oscillations and a narrow central peak of order ${\displaystyle 1/T}$. Sub-natural linewidth spectroscopy is possible!

Note: if ${\displaystyle S(t)=(1+\alpha \cos(\omega _{0}t+\phi ))e^{-\Gamma t}}$, and ${\displaystyle \phi }$ is random, then one can only measure ${\displaystyle |F+iG|^{2}}$. Thus sub-natural spectroscopy requires information on the phase of the signal at ${\displaystyle t=0}$.

Three-Level System

Introduction

Many interesting phenomena occur when we consider a three-level system coupled by EM radiation, such as EIT (Electromagnetically Induced Transparency, STIRAP (Stimulated Raman Adiabatic Passage), VSCPT (Velocity-Selective Coherent Population Trapping), Lasing without inversion, slowing and stopping of light, quantum memory, etc. We can consider the uncoupled levels to be internal atomic states. The interaction with coherent radiation (e.g. laser beams) "dresses" these states and the new eigenstates are coherent superpositions of the internal atomic states. On a next level of complication, we can include the mechanical effects of the radiation and consider as uncoupled states ${\displaystyle |\mathrm {internal} \rangle |\mathrm {external} \rangle }$ states. The radiation can then impart momentum, known as recoil momentum.

There are three basic configurations: V-type, ${\displaystyle \Lambda }$-type, and Ladder type.

Here we focus on the ${\displaystyle \Lambda }$-type. We can think of ${\displaystyle |g_{1}\rangle ,|g_{2}\rangle }$ as two metastable states, for example, two hyperfine states in alkali atoms or the singlet and triplet lowest-energy states of alkaline earth atoms. They may or may not be degenerate. We assume that the direct transition between them is strongly suppressed, so they are only coupled to the excited state ${\displaystyle |e\rangle }$. The coupling strengths are the Rabi frequencies ${\displaystyle \Omega _{1}={\frac {d_{1}\cdot E_{1}}{\hbar }}}$ and ${\displaystyle \Omega _{2}={\frac {d_{2}\cdot E_{2}}{\hbar }}}$ (in the Electric Dipole Approximation).

Optical Pumping

The simplest case of a 3-level system interacting with an EM field is Optical Pumping, which means that all the population is "pumped" into one state (e.g. ${\displaystyle |g_{1}\rangle }$ or ${\displaystyle |g_{2}\rangle }$). This state could be bright or dark (interacting with the light or not). For example, a dark state pumping scheme can be achieved in a ${\displaystyle \Lambda }$ system by turning on only one laser beam (${\displaystyle \Omega _{1}\neq 0,\Omega _{2}=0}$) which transfers all the atoms into the uncoupled state (in this case ${\displaystyle |g_{2}\rangle }$).

Another example of Optical Pumping, which does not involve a dark state but rather a cycling transition, is pumping into a Zeeman sublevel of one of the ground state. This can be done in a multilevel system with resolved Zeeman sublevels. The state into which the population is pumped is coupled only to one excited state and that excited state can decay only to the state into which we pump: the population ends up cycling between the two.

In both of these cases, a significant fraction of the population is transferred into the excited state from which it can spontaneously decay. However, other schemes can be used in which the population is coherently transferred between different ground states with only small fraction of the population ending up in the excited state. Several such examples are discussed below.

Dark State (On Resonant Case)

Assume the semiclassical Hamiltonian with the rotating wave approximation for the system.

${\displaystyle H=\hbar \omega _{1e}|e\rangle \langle e|+\hbar \delta |g2\rangle \langle g2|}$

${\displaystyle +{\frac {\hbar \Omega _{1}}{2}}\left(|e\rangle \langle g1|e^{-i\omega _{1}t}+|g1\rangle \langle e|e^{i\omega _{1}t}\right)+{\frac {\hbar \Omega _{2}}{2}}\left(|e\rangle \langle g2|e^{-i\omega _{2}t}+|g2\rangle \langle e|e^{i\omega _{2}t}\right)}$

The second line is the interaction term. Define this as ${\displaystyle {\hat {V}}}$. Be careful about the notation in ${\displaystyle \omega }$ s. ${\displaystyle \omega }$s are for energy scale. ${\displaystyle \omega _{1}e}$ and ${\displaystyle \omega _{2}e}$ are the energy difference of three states. ${\displaystyle \omega _{1}}$ and ${\displaystyle \omega _{2}}$ are the frequency of two lasers. ${\displaystyle \Omega }$s show the coupling strength and ${\displaystyle \Omega _{1}}$ and ${\displaystyle \Omega _{2}}$ correspond to the coupling of ${\displaystyle |g1\rangle }$ and ${\displaystyle |g2\rangle }$ and the excited state. Transforming this to the proper rotating frame, you can get rid of the exponential factors.

When the lasers are on resonant to the energy level difference, the Hamiltonian in the matrix form is as follows.

${\displaystyle {\begin{pmatrix}0&{\frac {\Omega _{1}}{2}}&0\\{\frac {\Omega _{1}}{2}}&0&{\frac {\Omega _{2}}{2}}\\0&{\frac {\Omega _{2}}{2}}&0\\\end{pmatrix}}}$

Diagonalizing this, you get the energy eigenvalues ${\displaystyle 0}$, ${\displaystyle -\hbar {\sqrt {\Omega _{1}^{2}+\Omega _{2}^{2}}}}$ and ${\displaystyle \hbar \left(\omega _{1e}+{\sqrt {\Omega _{1}^{2}+\Omega _{2}^{2}}}\right)}$ and corresponding eigenstates ${\displaystyle {\frac {\Omega _{2}}{\sqrt {\Omega _{1}^{2}+\Omega _{2}^{2}}}}|g1\rangle -{\frac {\Omega _{1}}{\sqrt {\Omega _{1}^{2}+\Omega _{2}^{2}}}}|g2\rangle }$, ${\displaystyle -{\frac {\Omega _{2}}{\sqrt {2\left(\Omega _{1}^{2}+\Omega _{2}^{2}\right)}}}|g1\rangle +{\frac {1}{\sqrt {2}}}|e\rangle -{\frac {\Omega _{1}}{2{\sqrt {\left(\Omega _{1}^{2}+\Omega _{2}^{2}\right)}}}}|g2\rangle }$ and ${\displaystyle {\frac {\Omega _{2}}{\sqrt {2\left(\Omega _{1}^{2}+\Omega _{2}^{2}\right)}}}|g1\rangle +{\frac {1}{\sqrt {2}}}|e\rangle +{\frac {\Omega _{1}}{2{\sqrt {\left(\Omega _{1}^{2}+\Omega _{2}^{2}\right)}}}}|g2\rangle }$ The first eigenstate is not mixed with the excited state, and therefore the photon cannot talk to this state. This state is called dark state.

This can be also proved by calculating

${\displaystyle \langle e|{\hat {V}}|D\rangle \propto \langle e|{\Bigl (}\Omega _{1}|e\rangle \langle g|+\Omega _{2}|e\rangle \langle f|{\Bigr )}|D\rangle =0}$

For ${\displaystyle \Omega _{1}\ll \Omega _{2}}$, the dark state is ${\displaystyle |g1\rangle }$. Dark state is predominantly the state with weaker coupling. The orthogonal superposition of two stable states is the bright state.

${\displaystyle |B\rangle ={\frac {\Omega _{1}}{\sqrt {\Omega _{1}^{2}+\Omega _{2}^{2}}}}|g\rangle +{\frac {\Omega _{2}}{\sqrt {\Omega _{1}^{2}+\Omega _{2}^{2}}}}|f\rangle }$

Coherent Population Trapping

When you have a three level system two of which are stable or metastable, you can make a coherent superposition of the two stable states by shining lasers. This phenomenon is called coherent population trapping.

The system is analyzed in the previous subsection. You have the dark state that does not talk with the photon and the bright state that talks with the photon. When you keep shining the photon, population in the bright state is excited to the excited state and the excited state can decay to both the dark state and the bright state. However, the dark state cannot be excited again. Therefore, population moves to the dark state in the same way as the optical pumping. Difference between the optical pumping is that the dark state is now the superposition of the two state. By adjusting the ratio of ${\displaystyle \Omega _{1}}$ and ${\displaystyle \Omega _{2}}$, you can make the arbitrary superposition of two stable states.

Effective 2-level System: Dark State (Off Resonant Case)

(Here we follow D. A. Steck, Quantum and Atom Optics, Chapter 6.)

Consider the ${\displaystyle \Lambda }$ configuration shown above and let's ignore the external degrees of freedom for now. If ${\displaystyle \Delta \gg \Omega ,\Gamma }$, we can treat the 3-level system as an effective two level system. ${\displaystyle \Delta }$ here is the detuning from the excited state (for each of the two lasers). One way to think about this is that each coupling beam creates a coherence between ${\displaystyle |g_{1}\rangle \longleftrightarrow |e\rangle }$ and ${\displaystyle |g_{2}\rangle \longleftrightarrow |e\rangle }$ respectively. This is similar to two dipoles oscillating in phase. The result is that population can be transferred coherently from one ground state to the other, without resorting to spontaneous emission from the excited states to transfer the atoms which could destroy this coherence. Another way to think about this process is that the two Raman beams can interfere, creating two beat frequencies, one of which can be tuned to the energy difference between the two ground states.

To mathematically describe the effective two-level system, we have to adiabatically eliminate the excited state from the discussion. To do this, we can first transform into a frame rotating at the laser frequencies. We pick the excited state as the energy reference and our state becomes:

${\displaystyle |\Psi \rangle ={\tilde {c}}_{1}|g_{1}\rangle +c_{e}|e\rangle +{\tilde {c}}_{2}|g_{2}\rangle }$

Here ${\displaystyle {\tilde {c}}_{1}=c_{1}e^{-i\omega _{1}t}}$ and ${\displaystyle {\tilde {c}}_{2}=c_{2}e^{-i\omega _{2}t}}$ are the slowly-varying amplitudes. For simplicity, we set: ${\displaystyle \Delta _{1}=\Delta _{2}=\Delta }$ (so that we are on two-photon resonance), ${\displaystyle \delta =0}$ (so that the two ground states are degenerate), and we pick the zero of the energy to be at ${\displaystyle |g\rangle }$. Then, in the RWA and in the rotating frame we just defined, and in the basis ${\displaystyle (|g_{1}\rangle ,|e\rangle ,|g_{2}\rangle )}$, the Hamiltonian is:

${\displaystyle {\begin{pmatrix}0&{\frac {\Omega _{1}}{2}}&0\\{\frac {\Omega _{1}}{2}}&\Delta &{\frac {\Omega _{2}}{2}}\\0&{\frac {\Omega _{2}}{2}}&0\\\end{pmatrix}}}$

From here, we can write the Schrodinger equation for the three amplitudes:

${\displaystyle {\begin{aligned}&i{\frac {\partial }{\partial t}}{\tilde {c}}_{1}={\frac {\Omega _{1}}{2}}c_{e}\\&i{\frac {\partial }{\partial t}}c_{e}={\frac {\Omega _{1}}{2}}{\tilde {c}}_{1}+{\frac {\Omega _{2}}{2}}{\tilde {c}}_{2}+\Delta c_{e}\\&i{\frac {\partial }{\partial t}}{\tilde {c}}_{2}={\frac {\Omega _{2}}{2}}c_{e}\end{aligned}}}$

We can now assume that the excited state amplitude evolves at a frequency determined by the detuning ${\displaystyle \Delta }$. But since we want ${\displaystyle \Delta }$ to be large compared to the timescale of the dynamics of the system (which is set by ${\displaystyle \Omega _{1},\Omega _{2}}$), we can neglect its time variation: ${\displaystyle {\frac {\partial }{\partial t}}c_{e}\approx 0}$. We can then solve the system of equations above by eliminating ${\displaystyle c_{e}}$ to get (now in the basis ${\displaystyle (|g_{1}\rangle |g_{2}\rangle )}$)

${\displaystyle {\begin{pmatrix}{\frac {\Omega _{1}^{2}}{4\Delta }}&{\frac {\Omega _{1}\Omega _{2}}{4\Delta }}\\{\frac {\Omega _{1}\Omega _{2}}{4\Delta }}&{\frac {\Omega _{2}^{2}}{4\Delta }}\\\end{pmatrix}}}$

We recognize the off-diagonal entries as the two-photon Rabi frequency. The eigenenergies and eigenstates are:

${\displaystyle {\begin{aligned}E_{D}=0&\longrightarrow |D\rangle =-{\frac {\Omega _{2}}{\sqrt {\Omega _{1}^{2}+\Omega _{2}^{2}}}}|g_{1}\rangle +{\frac {\Omega _{1}}{\sqrt {\Omega _{1}^{2}+\Omega _{2}^{2}}}}|g_{2}\rangle \\E_{B}={\frac {\Omega _{1}^{2}+\Omega _{2}^{2}}{4\Delta }}&\longrightarrow |B\rangle ={\frac {\Omega _{1}}{\sqrt {\Omega _{1}^{2}+\Omega _{2}^{2}}}}|g_{1}\rangle +{\frac {\Omega _{2}}{\sqrt {\Omega _{2}^{2}+\Omega _{2}^{2}}}}|g_{2}\rangle \end{aligned}}}$

The dark state ${\displaystyle |D\rangle }$ is the coherent superposition of uncoupled states which does not interact with the light.

External states: VSCPT

If we now include the mechanical action of the laser beams, the atoms will acquire momentum when they absorb or emit photons. We now describe our system with the uncoupled states ${\displaystyle |internal\rangle |external\rangle }$, as in the figure.

This system still has a dark state but now this state depends on the velocity of the atoms. This makes it possible to put in the dark state only atoms with a given velocity (${\displaystyle v\pm \Delta v}$). This velocity can be picked by changing the relative detuning of the two beams. The technique of targeting atoms with a certain velocity can be used to produce cold atomic samples with subrecoil velocity spread.

Consider two counterpropagating beams with frequency difference ${\displaystyle \Delta \omega }$ on resonance with the 1-photon transition from ${\displaystyle |g\rangle }$ to ${\displaystyle |e\rangle }$. Let the atoms start in ${\displaystyle |g\rangle }$ with momentum ${\displaystyle {\vec {p}}_{1}}$ and let their momentum after interacting with the laser beams be ${\displaystyle p_{2}}$. Let's neglect spontaneous emission for now.

From energy and momentum conservation (in 1D):

${\displaystyle {\begin{aligned}\hbar k+p_{1}=-\hbar k+p_{2}\\\hbar \omega +{\frac {p_{1}^{2}}{2m}}=\hbar (\omega +\Delta \omega )+{\frac {p_{2}^{2}}{2m}}\\\Longrightarrow p_{1(2)}={\frac {m\Delta \omega }{2\hbar k}}\pm \hbar k\end{aligned}}}$