Difference between revisions of "Coherence"

Latest revision as of 17:11, 24 May 2022

1 Introduction
2 Spontaneous Emission
3 Coherence in two-level systems
4 Three-Level System
5 Electromagnetically induced transparency
6 EIT: Eigenstates picture
7 STIRAP in a three-level system
8 Example: Five-level non-local STIRAP
9 On the "magic" of dark-state adiabatic transfer
10 Two-photon absorption features. Fano profiles
11 Slow light, adiabatic changes of velocity of light
12 Superradiance
13 Superradiance, continued
14 Supperradiance in N atoms
15 Dicke states of extended samples
16 Oscillating and overdamped regimes of superradiance
17 Raman Superradiance
18 Storing light, catching photons
19 Notes

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. $|\langle \phi |\psi \rangle |^{2}$ .

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. $\Omega _{\text{Rabi}}\gg \Gamma$ . 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 $\Omega _{\text{Rabi}}$ (e.g. a strong laser).

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

▼ Category:8.421

► Category:Atoms in electric fields

Atoms

Atoms in electric fields

Atoms in Magnetic Fields

Coherence

Effects of the Nucleus on Atomic Structure

Fine Structure and Lamb Shift

Higher-Order Radiation Processes

Interaction of an atom with an electromagnetic field

Old Coherence

Resonances

Two-Photon Excitation

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 $\sum _{\text{modes}}{\frac {\omega _{R}}{2}}(\sigma ^{+}a+\sigma ^{-}a^{+})$ , 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 $\pi /2$ pulse in a superposition $1/{\sqrt {2}}(|g\rangle +e^{-i\phi _{0}}|e\rangle )\otimes |0\rangle$ , where $|0\rangle$ 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 $\phi _{0}$ between $|e\rangle$ and $|g\rangle$ is well defined, and the system will evolve coherently as $1/{\sqrt {2}}(|g\rangle +e^{-i(\omega _{o}t+\phi _{0})}|e\rangle )\otimes |0\rangle$ . This occurs for times $t\leq \ 1/\omega _{1}$ , where $\omega _{1}$ is the vacuum Rabi oscillation frequency, after which $|e\rangle \otimes |0\rangle \longrightarrow |g\rangle \otimes |1\rangle$ . After this "spontaneous emission" has occurred the state of the system is $|g\rangle \otimes (1/{\sqrt {2}}(|0\rangle +e^{-i(\omega _{o}t+\phi _{0})}|1\rangle )$ , 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

\pi /2

pulse. The laser light is sent through both arms of an interferometer; a switch in one arm selects a

\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

\pi /2

pulse.

What about an atom prepared by a $\pi$ pulse in $|e\rangle$ ? There is no coherence at $t=0$ , since the atom is in a single state, but what about $t=1/(\omega _{1}/2)$ ? Then the atom is in a superposition of states $\sim |g\rangle +e^{-i\omega _{0}t+\phi _{0}}|e\rangle$ . Obviously some phase must exist, because otherwise no dipole moment ${\bf {d}}(t)=\langle e(t)|q{\bf {r}}|g(t)\rangle$ exists that can emit, but the phase $\phi _{0}$ 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 ( $\int _{0}^{2\pi }d\phi \langle e|e^{i\phi }q{\bf {r}}|g\rangle =0$ ). We conclude that an atom prepared in $|e\rangle$ 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 $\langle d(t)\rangle =0$ is zero at all times (but $\langle d^{2}\rangle \neq 0$ !). What is the origin of this uncertain phase $\phi _{o}$ ? 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 $|\psi \rangle =C_{g}|g\rangle +C_{e}|e\rangle$ . Then, the coherence between $|e\rangle$ and $|g\rangle$ is maximum for $C_{e}=C_{g}=1/{\sqrt {2}}$ , i.e. with a $\pi /2$ pulse. Indeed, recall that the coherences are the off-diagonal elements of the density matrix, $\rho _{ab}$ . For a pure state, they are $C_{g}C_{e}^{*}$ 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: $|g,1\rangle$ and $|e,0\rangle$ . Thus, a $\pi /2$ pulse also maximizes the coherence $|g,1\rangle$ and $|e,0\rangle$ .

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

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

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

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

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

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

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

Stern-Gerlach experiment. Where, in the magnet or outside, does the projection onto

|\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 $|x\rangle$ has equal probability of following either the $|+z\rangle$ trajectory or the $|-z\rangle$ trajectory. So initially the particle is described by a density matrix for a pure state,

\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

\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

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

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

Using the density matrix formalism:

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

And so the spin coherence as earlier defined is simply:

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

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

The coherence (interference) between $|+z\rangle$ and $|-z\rangle$ components to form $|x\rangle$ thus exists only in the region where there is at least partial overlap between the two wavefunctions $\psi _{+z}({\bf {r}}),\psi _{-z}({\bf {r}})$ . When the wavefunctions do not overlap, there is no significance to a relative phase between $|+z\rangle$ and $|-z\rangle$ , 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 $|+z\rangle$ and $|-z\rangle$ giving rise to $|x\rangle$ disappears. In a measurement language, the inhomogeneous magnetic field entangles the "variable" ( $|\pm z\rangle$ ) with the "meter" (the spatial wavefunctions of the particle). Once the spatial wavefunctions $\psi _{+z}({\bf {r}}),\psi _{-z}({\bf {r}})$ cease to overlap, the particle's position can serve as a "meter" for the variable to be measured, the spin along $\pm z$ . 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

\hbar \Delta

from ground state,

\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 $\hbar \Delta$ , all decaying to a common ground state. If we excite with a pulse of duration $\Delta t\ll 1/\Delta$ (or a broadband source), we cannot resolve the levels, and they will be populated according to the coupling strength to the ground state $|g\rangle$ for the given excitation method:

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

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

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

It follows that, in directions where the radiation from levels $|e^{(i)}\rangle$ and $|e^{(j)}\rangle$ interferes, there will be oscillating terms at frequencies $\omega _{i}-\omega _{j}$ 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 $|\psi (t)\rangle$ above ), while no coherence between $|e^{(i)}\rangle$ and $|g\rangle$ exists initially. Of course, as the atom decays, coherences between $|e^{(i)}\rangle$ and $|g\rangle$ (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

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

Our signal is:

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

,

whose Fourier Transform is a Lorentzian

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

,

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

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

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

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

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

\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 $T$ :

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

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

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

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 $|\mathrm {internal} \rangle |\mathrm {external} \rangle$ states. The radiation can then impart momentum, known as recoil momentum.

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

Here we focus on the $\Lambda$ -type. We can think of $|g_{1}\rangle ,|g_{2}\rangle$ 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 $|e\rangle$ . The coupling strengths are the Rabi frequencies $\Omega _{1}={\frac {d_{1}\cdot E_{1}}{\hbar }}$ and $\Omega _{2}={\frac {d_{2}\cdot E_{2}}{\hbar }}$ (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. $|g_{1}\rangle$ or $|g_{2}\rangle$ ). 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 $\Lambda$ system by turning on only one laser beam ( $\Omega _{1}\neq 0,\Omega _{2}=0$ ) which transfers all the atoms into the uncoupled state (in this case $|g_{2}\rangle$ ).

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.

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

+{\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 ${\hat {V}}$ . Be careful about the notation in $\omega$ s. $\omega$ s are for energy scale. $\omega _{1}e$ and $\omega _{2}e$ are the energy difference of three states. $\omega _{1}$ and $\omega _{2}$ are the frequency of two lasers. $\Omega$ s show the coupling strength and $\Omega _{1}$ and $\Omega _{2}$ correspond to the coupling of $|g1\rangle$ and $|g2\rangle$ 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.

{\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 $0$ , $-\hbar {\sqrt {\Omega _{1}^{2}+\Omega _{2}^{2}}}$ and $\hbar \left(\omega _{1e}+{\sqrt {\Omega _{1}^{2}+\Omega _{2}^{2}}}\right)$ and corresponding eigenstates ${\frac {\Omega _{2}}{\sqrt {\Omega _{1}^{2}+\Omega _{2}^{2}}}}|g1\rangle -{\frac {\Omega _{1}}{\sqrt {\Omega _{1}^{2}+\Omega _{2}^{2}}}}|g2\rangle$ , $-{\frac {\Omega _{2}}{\sqrt {2\left(\Omega _{1}^{2}+\Omega _{2}^{2}\right)}}}|g1\rangle +{\frac {1}{\sqrt {2}}}|e\rangle -{\frac {\Omega _{1}}{2{\sqrt {\left(\Omega _{1}^{2}+\Omega _{2}^{2}\right)}}}}|g2\rangle$ and ${\frac {\Omega _{2}}{\sqrt {2\left(\Omega _{1}^{2}+\Omega _{2}^{2}\right)}}}|g1\rangle +{\frac {1}{\sqrt {2}}}|e\rangle +{\frac {\Omega _{1}}{2{\sqrt {\left(\Omega _{1}^{2}+\Omega _{2}^{2}\right)}}}}|g2\rangle$ 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

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

|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 $\Omega _{1}$ and $\Omega _{2}$ , 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 $\Lambda$ configuration shown above and let's ignore the external degrees of freedom for now. If $\Delta \gg \Omega ,\Gamma$ , we can treat the 3-level system as an effective two level system. $\Delta$ 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 $|g_{1}\rangle \longleftrightarrow |e\rangle$ and $|g_{2}\rangle \longleftrightarrow |e\rangle$ 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:

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

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

{\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:

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

{\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:

{\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 $|D\rangle$ 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 $|internal\rangle |external\rangle$ , 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 ( $v\pm \Delta v$ ). 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 $\Delta \omega$ on resonance with the 1-photon transition from $|g\rangle$ to $|e\rangle$ . Let the atoms start in $|g\rangle$ with momentum ${\vec {p}}_{1}$ and let their momentum after interacting with the laser beams be $p_{2}$ . Let's neglect spontaneous emission for now.

From energy and momentum conservation (in 1D):

{\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}}

So that only atoms with initial momentum $p_{1}\pm$ will satisfy the Raman resonance condition and will interact with the two beams and can be pumped into a dark state. \\

We can analyze the 3-level velocity-dependent system in the same way we analyzed the internal-state 3-level system. Let's assume for simplicity that $\Delta \omega =0$ . The 3 levels are $|g,\hbar k\rangle ,|e,0\rangle ,|g,-\hbar k\rangle$ . The dark state is:

|D\rangle ={\frac {1}{\sqrt {2}}}\left(c_{1}|g_{1},-\hbar k\rangle +c_{2}|g_{2},+\hbar k\rangle \right)

We can see that now internal and external states are entangled.

If we include spontaneous emission at rate $\Gamma$ , the energy level of the excited state essentially broadens. Then, there are more levels to which we can couple, such as $|e,\pm 2\hbar k\rangle$ , which in turn can couple to $|g,\pm 3\hbar k\rangle$ . These transitions have different resonant frequencies, shifted by $\Delta E\propto E_{r}={\frac {\hbar ^{2}k^{2}}{2m}}$ . If the width of the excited state $\Gamma \gg E_{r}/\hbar$ , these transitions contribute and the dark state disappears (or at least decreases in "darkness"). However, a small $\Gamma$ just broadens the width of the k-space distributions in the dark state.

Such a dark state has been observed in VSCPT experiments: the momentum distribution consists of two peaks centered at $\pm \hbar k$ . See, for example, the first observation of Cooling below the single photon recoil limit by vscpt (Phys. Rev. Lett. 61, 826 (1988))

Manipulating atoms with photons, Cohen-Tannoudji (Rev. Mod. Phys. 70, 707)

Atoms in time of flight after the application of Raman beams. They split into two groups with momenta $\hbar k$ and $-\hbar k$ respectively.

STIRAP

What happens if you change $\Omega _{1}$ and $\Omega _{2}$ slowly, i.e. adiabatically? Stimulated Raman adiabatic passage, STIRAP, is an application for this situation.

For simplicity, let's assume that $\delta =0$ and lasers are blue detuned. You first turn up the laser 2 and then turn up the laser 1, turning down the laser 2. In the end, you turn down the laser 1. In this condition, the dark state is initially $|g1\rangle$ , as $\Omega _{2}\neq 0$ . Then the dark state gradually becomes $|g2\rangle$ . Thus, you can coherently move the population from $|g1\rangle$ to $|g2\rangle$ . Here, the dark state is the lowest energy state, because it has no AC Stark shift, whereas the energy level of the bright state goes up due to the blue detuned light. The pulse sequence is counter-intuitive. In order to talk to the atoms in $|g1\rangle$ , you first turn up the laser that connects $|e\rangle$ and $|g2\rangle$ .

When you have the red detuned light and when $|g1\rangle$ and $|g2\rangle$ are not degenerate, you get the same result. In these cases, $|g1,N_{1},N_{2}\rangle$ and $|g2,N_{1}-1,N_{2}-1\rangle$ are generate, where $N_{1}$ and $N_{1}$ are the photon number for the laser 1 and 2.

STIRAP is a dark state transfer. How can we go from $|g1\rangle$ to $|g2\rangle$ without building up population in $|e\rangle$ ? The answer is, there is a slight population in $|e\rangle$ . Let's check this with Schrödinger equation.

{\begin{aligned}i\left({\begin{array}{c}{\dot {c}}_{g1}\\{\dot {c}}_{e}\\{\dot {c}}_{g2}\end{array}}\right)=\left({\begin{array}{ccc}0&\Omega _{1}/2&0\\\Omega _{1}/2&0&\Omega _{2}/2\\0&\Omega _{2}/2&0\end{array}}\right)\left({\begin{array}{ccc}c_{g1}\\c_{e}\\c_{g2}\end{array}}\right)\end{aligned}}

{\dot {c}}_{g2}=i{\frac {\Omega _{2}}{2}}c_{e}

As we want $|c_{g2}|=1$ after the time for the transfer,

c_{e}\approx {\frac {1}{\Omega _{2}t_{\rm {transfer}}}}

p_{e}\sim {\frac {1}{\Omega _{2}^{2}t_{\rm {transfer}}^{2}}}

The probability for the spontaneous emission is

\Gamma \rho _{e}\approx {\frac {\Gamma }{\Omega _{2}^{2}t_{\rm {transfer}}^{2}}}\rightarrow 0

as $\Omega _{2}\rightarrow \infty$ or $t_{\rm {transfer}}\rightarrow \infty$ . However, $t_{\rm {transfer}}$ has to be smaller than coherent time of the $|g1\rangle$ and $|g2\rangle$ states. The point here is that the rate of the state transfer is proportional to the amplitude of the excited state. In this sense, the transfer is more efficient than optical pumping, whose rate of the transfer is proportional to the population of the excited state. Since the spontaneous emission from the excited state is proportional to the population, this incoherent process is suppressed in STIRAP by the factor of ${\frac {1}{\Omega _{2}t_{\rm {transfer}}}}$ . When you compare STIRAP with two photon Rabi flipping, that is, two photon $\pi$ pulse, the efficiency is the same. The reason STIRAP is better is that STIRAP has some robustness that two photon $\pi$ pulse does not have. It does not get as much effect by the frequency instability as Rabi scheme, and you don't have to worry about the exact length of the pulse in STIRAP.

Gain without Inversion

When you have a laser, common belief is that you need to have more atoms in excited state than ground state. However, this is not necessarily the same for the three level system B system with two unstable states that decay by coupling to the same continuum (i.e. same polarization). Suppose you send the population from the ground state by shining a laser of a frequency between two excited state energy. The matrix element for the transition by the second order perturbation theory is

{\cal {M}}=\sum _{j=1,2}{\frac {\langle {\rm {cont}}|V|e_{j}\rangle \langle e_{j}|V|g\rangle }{\Delta _{j}-i\Gamma _{j}/2}}

There is an $\omega _{0}$ for which the two terms almost cancel, when $|\Delta _{1}|,\ |\Delta _{2}|\gg \Gamma _{1},\ \Gamma _{2}$ . When you have atoms in the ground state and the laser frequency is $\omega _{0}$ , you will see a quantum interference due to the multiple paths to the continuum. When you have a population in $|e_{2}\rangle$ state that is much smaller than that in the ground state and you shine the $\omega _{0}$ laser, you see the light due to the laser itself plus the induced emission of $\omega _{0}$ from $|e_{2}\rangle$ . There is a gain in this frequency though there is no population inversion. In other words, there is destructive interference between $|e_{1}\rangle$ and $|e_{2}\rangle$ for the absorption from the ground state, but not for the gain.

There are some possible realization for this system. One is hydrogen and DC electric field. The mixing of 2S state and 2P state by the DC electric field gives two wide field. Another is to use AC electric field to mix the S state and P state. If you have $\Lambda$ system with two degenerate ground state, you can make a gain without inversion by distributing the population as follows: none in $|g\rangle$ , a little in $|e\rangle$ and most in $|f\rangle$ , whose population is hidden.

For more detailed discussion, refer to Phys. Rev. Lett. 62, 1033.

http://prl.aps.org/abstract/PRL/v62/i9/p1033\_1

Electromagnetically induced transparency

EIT in the dressed state picture

"Is it possible to send a laser beam through a brick wall?"

Radio Yerevan: "In principle yes, but you need another very powerful laser..."

The light interaction Hamiltonian in the dipole approximation is $H_{\text{int}}=-\mathbf {d} \cdot \mathbf {E}$ , where the dipole operator $\mathbf {d} =\mathbf {d_{1}} +\mathbf {d_{2}}$ is comprised of individual dipole moments $\mathbf {d_{1}}$ and $\mathbf {d_{2}}$ corresponding to the transitions $|g_{1}\rangle \leftrightarrow |e\rangle$ and $|g_{2}\rangle \leftrightarrow |e\rangle$ , respectively. In expanding out the interaction Hamiltonian we drop the cross terms $\mathbf {d_{2}} \cdot \mathbf {E_{1}}$ , thus assuming that $\mathbf {E_{1}}$ does not couple $g_{2}\rangle \leftrightarrow |e\rangle$ and visa versa (this assumption is justified if the ground state splitting is much larger than the detuning of the light fields). The interaction Hamiltonian then becomes

H_{\text{int}}=-\mathbf {d_{1}} \cdot \mathbf {E_{1}} \cos(\omega _{L,1})-\mathbf {d_{2}} \cdot \mathbf {E_{2}} \cos(\omega _{L,2})=\hbar \Omega _{1}|e\rangle \langle g_{1}|\cos(\omega _{L,1}t)+\hbar \Omega _{2}|e\rangle \langle g_{2}|\cos(\omega _{L,2}t)+h.c.

where we have introduced the Rabi frequencies, $\Omega _{i}=-\langle g_{i}|\mathbf {d_{i}} \cdot \mathbf {E_{i}} |e\rangle /\hbar$ .

As usual in semi-classical light matter interaction problems, we switch to the rotating frame of the light field defined by

|{\tilde {\Psi }}\rangle =c_{1}(t)e^{-i\omega _{L,1}t}|g_{1}\rangle +c_{2}(t)e^{-i\omega _{L,2}t}|g_{2}\rangle +c_{3}(t)|e\rangle

.

The total Hamiltonian in this new basis is thus

{\tilde {H}}_{0}+{\tilde {H}}_{\text{int}}={\dfrac {\hbar }{2}}\left({\begin{array}{ccc}0&\Omega _{1}&\Omega _{2}\\\Omega _{1}&2\Delta _{1}&0\\\Omega _{2}&0&2\Delta _{2}\end{array}}\right)

Steve Harris thought initially of special, ionizing excited states. However it is possible to realize the requirement of identical decay paths in a $\lambda$ -system with a a(strong) coupling laser. The phenomenon is closely related to coherent population trapping.

For resonant fields $\omega _{1}=\omega _{ge},\omega _{2}=\omega _{fe}$ , we have

As we turn up the power of the coupling laser the transmission improves and then broadens (in the realistic case of a finite decoherence rate $\gamma _{gf}=0$ , an infinitesimally small coupling Rabi frequency, but the frequency window over which transmission occurs is very narrow and given by $\Delta \omega =\Omega _{c}$ .

EIT vs CPT. What's the difference?

Sometimes in the literature CPT and EIT are treated as two different phenomena, while here we have treated the two with a similar formulation. Are they different? The short answer is no. The long answer is that CPT is a "trapping" effect, and relies on spontaneous emission to produce the coherent dark state (i.e., spontaneous emission allows for the system to undergo a random walk in phase space until it falls into a "trapped" state, no longer coupled to spontaneous emission). For example, in VSCPT, very low temperatures are attained because the the atoms undergo many spontaneous emission events and are pumped into the dark state. On the other hand EIT experiments are usually prepared adiabatically: A strong pump beam initializes the atomic state, and then the weak probe beam adiabatically prepares the dark state, with no spontaneous emission. Another contrast is that CPT experiments focus on trapping of atoms, while EIT experiments are more concerned with the effect of the atoms on cross-modulating the two light beams. However, the underlying physics for both effects is the same.

Further theoretical treatment

The approach to EIT presented here has relied greatly on intuition. For the interested reader, there are two very interesting approaches not covered here. The first is using the optical Bloch equations (which are outside the scope of 8.421) to treat the effect of spontaneous emission explicitly, and thus calculate the widths of the EIT resonance feature. A good resource for this is the section "Master equation and linear susceptibility" in Rev. Mod. Phys. 77, 633 (2005). http://journals.aps.org/rmp/abstract/10.1103/RevModPhys.77.633

Another approach is to ask the question: Is EIT a quantum effect? In many ways it is not, and it can be modeled by a coupled system of two mass-spring harmonic oscillators, which is studied in careful detail here: http://arxiv.org/abs/quant-ph/0107061 .

EIT: Eigenstates picture

Using the field quantization to easily include energy conservation, we see that the states are coupled in triplets.

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We can go into the dressed atom picture and use the uncoupled states as our basis states. (Note: in the dressed-atom picture, the levels are denoted by $|\mathrm {atom} \rangle |\mathrm {photon} \rangle$ . The atom, in this case, is in one of the three states $|g\rangle ,|e\rangle ,|f\rangle$ and the photon is in a Fock state (a state with fixed photon number) with photon numbers $n$ and $m$ .

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The Rabi frequencies for the two transitions are $g_{1}{\sqrt {n}},g_{2}{\sqrt {m}}$ and the Hamiltonian written in the basis $\left(|g,n,m-1\rangle ,|e,n-1,m-1\rangle ,|f,n-1,m\rangle \right)$ is:

{\begin{aligned}H=\hbar \left({\begin{array}{ccc}0&g_{1}{\sqrt {n}}&0\\g_{1}{\sqrt {n}}&\Delta &g_{2}{\sqrt {m}}\\0&g_{2}{\sqrt {m}}&-\delta \end{array}}\right)\end{aligned}}

On resonance $\Delta =\delta =0$ the Eigenstates are

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|B1\rangle =g_{1}{\sqrt {n}}\;|g,n,m-1\rangle +{\sqrt {ng_{1}^{2}+mg_{2}^{2}}}\;|e,n-1,m-1\rangle +g_{2}{\sqrt {m}}\;|f,n-1,m\rangle

|D\rangle =g_{2}{\sqrt {m}}\;|g,n,m-1\rangle +g_{1}{\sqrt {n}}\;|f,n-1,m\rangle

|B2\rangle =g_{1}{\sqrt {n}}\;|g,n,m-1\rangle -{\sqrt {ng_{1}^{2}+mg_{2}^{2}}}\;|e,n-1,m-1\rangle +g_{2}{\sqrt {m}}\;|f,n-1,m\rangle

Note: these are unnormalized.

To understand the role of path interference in the formation of EIT, let's consider the limit of weak probe and a strong pump: $n\ll m$ . We can limit the analysis to $n=1$ . Then we can diagonalize the strong coupling, and treat the probe perturbatively. From the diagonalization above, we can see that in this limit the dark state is mostly the $|g,1,m\rangle$ state and the bright states are strong superpositions of $|e,0,m\rangle ,|f,0,m+1\rangle$ .

We want to know if the probe beam is absorbed and with what probability. We consider the problem in which we start with one photon in the probe beam and 0 photons in all other modes except in the pump mode (which we omit in the notation for simplicity), i.e. in $|g,0\rangle |0,\cdots 0,\cdots \rangle$ . That is, we want the final state to be $|g,0\rangle |0,\cdots 1,0,\cdots \rangle$ . Absorption of this photon has to be accompanied by emission, making this a two-photon scattering problem. There are two paths the photon can take: either via $|B1'\rangle$ or via $|B2'\rangle$ . The matrix element contains two intermediate states with opposite detunings. Calling the perturbing Hamiltonian V for simplicity, we get that the transition amplitude is:

$M={\frac {\langle g,0|\langle 0,\cdots 1,0\cdots |V'|B1'\rangle \langle B1'|V|g,1\rangle |0,\cdots 0,\cdots \rangle }{-\Delta '/2}}+{\frac {\langle g,0|\langle 0,\cdots 1,0\cdots |V|B2'\rangle \langle B2'|V|g,1\rangle |0,\cdots 0,\cdots \rangle }{\Delta '/2}}$

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On one- and two-photon resonance all couplings are symmetric in $|B1'>$ and $|B2'>$ , the detunings are opposite, and the matrix element M vanishes: electromagnetically induced transparency (EIT) - the photon in not absorbed. If the pump remains on resonance and we tune the probe field, then the couplings are still symmetric in $|B1'\rangle$ , $|B2'\rangle$ , but the detunings are ${\frac {\bar {\Delta '}}{2}}\pm \delta$ , and the matrix element does not vanish. Maximum scattering is obtained when we tune to one of the bright states.

File:Slide2.jpg

The figure shows the absorption of the probe beam. The frequency of the probe beam is $\omega _{p}$ and the frequency difference between the bring and the dark state is $\omega _{BD}$ . In the case of strong pump, this is the Rabi frequency $\Delta '/2$ above). (a) $\Delta '\leq \Gamma$ ; (b) $\Delta '\gg \Gamma$ . Figure adapted from Rev.Mod.Phys. 77, 633

When we include the decay $|e\rangle \rightarrow |g\rangle ,|f\rangle$ within the system, we can no longer use the Hamiltonian formalism, but must use density matrices. Nevertheless, the eigenstates provide physical insight into the problem.

STIRAP in a three-level system

If at least one of the two coupling beams is non-zero, there is always a finite energy spacing between the dark state and the bright states. This allows one, by changing the ration of the coupling beams, to adiabatically change the character of the dark state between |g> and |f> while not populating the bright states (and thus the excited state). By use of the so-called "counterintuitive pulse sequence"

STIRAP of this type in a three-level system is also called "dark-state transfer."

Example: Five-level non-local STIRAP

Atom A contains hyperfine excitation, can we transfer the hyperfine excitation from A to B without losing it from the cavity? Cavity strongly coupled to A,B with single-photon Rabi frequency g. Dark-state adiabatic transfer with virtual excitation of the cavity mode is possible:

Procedure: turn on $\omega _{B}$ first coupling empty level, ramp up $\omega _{A}$ , ramp down $|\omega _{B}\rightarrow$ adiabatic transfer $|g_{A}\rangle |\delta \rangle _{B}|0\rangle _{c}\rightarrow |\delta \rangle _{A}|g\rangle _{B}|0\rangle _{c}$ via dark state of the cavity. Note that the probability to find the photon in the cavity can be made very small while maintaining full transfer: virtual states.

If we stop the transfer suddenly half-way we create an entangled state where the single hyperfine excitation is shared between the two samples.

Verification and entanglement:

${\frac {1}{\sqrt {2}}}(|g\rangle |f\rangle +e^{i\phi }|f\rangle |g\rangle )$ well-defined phase must exist

How to verify? Simultaneous readout, super and sub radiant states

The dipole moments $d_{ge}$ (emitted fields on the ge transition) of the two atoms can interfere.

Interference fringe can only be observed if state is entangled. Fringe is due to interference if dipole moments between <underline> <attributes> </attributes> different </underline> atoms.

On the "magic" of dark-state adiabatic transfer

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How is it that we can transfer the population completely form state |g> to state |f> through the state |e> while keeping the unstable state |e> unpopulated? (The correct statement is "...while keeping the population of |e> negligibly small"). This is possible through coherence-interference: on resonance the eqs of motion for the amplitudes of the three states read

{\begin{aligned}i\left({\begin{array}{c}C_{g}\\C_{e}\\C_{f}\end{array}}\right)=\left({\begin{array}{ccc}0&{\frac {\omega _{1}}{2}}&0\\{\frac {\omega _{1}}{2}}&0&{\frac {\omega _{2}}{2}}\\0&{\frac {\omega _{2}}{2}}&0\end{array}}\right)\left({\begin{array}{c}C_{g}\\C_{e}\\C_{f}\end{array}}\right)\end{aligned}}

${\dot {C}}_{g}=-i{\frac {\omega _{1}}{2}}C_{e}$ ${\dot {C}}_{e}=-i{\frac {\omega _{1}}{2}}C_{g}-i{\frac {\omega _{2}}{2}}C_{f}$ ${\dot {C}}_{f}=-i{\frac {\omega _{2}}{2}}C_{e}$

Let's assume initially $C_{g}(t=0)=1,C_{e}(t=0)=0,C_{f}(t=0)=0$ .

For adiabatic transfer we have $\omega _{2}\gg \omega _{1}$ and amplitude flow as

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So we see how $|f\rangle$ accumulates amplitude because it arrives there always with the same phase factor -1, whereas the flow back from $|f\rangle$ into $|e\rangle$ leads to a destructive interference in $|e\rangle$ with the amplitude flow from $|g\rangle$ , keeping the amplitude in $|e\rangle$ small at all times, while the amplitude on $|f\rangle$ keeps growing. If the state $|f\rangle$ were to acquire a random phase relative to $|g\rangle$ due to some other interaction, then the constructive interference leading to the accumulation of amplitude in $|f\rangle$ and the destructive interference in $|e\rangle$ would not work. The dark state transfer requires g-f coherence.

Two-photon absorption features. Fano profiles

We start with a 3-level system we have seen before but now we assume large one-photon detuning, $\Delta _{1},\Delta _{2}\gg \Gamma$ , weak probe (Rabi frequency $\Omega _{1}$ ) and strong pump field (Rabi frequency $\Omega _{2}$ ) and let's define the two-photon detuning $\delta =\Delta _{1}-\Delta _{2}$ .

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In this limit analytic expressions for the absorption cross section for beam $\Omega _{1}$ and the refractive index seen by beam $\Omega _{1}$ exist, e.g. [Muller et al., PRA 56, 2385 (1997)]

The refractive index is given by: $n(\delta )=1+{\frac {3}{8\pi ^{2}}}{\tilde {n}}\lambda ^{3}f(\delta )$

where ${\tilde {n}}$ is the atomic density, $f(\delta )={\frac {\Gamma }{2}}\delta {\frac {A}{A^{2}+B^{2}}},A=\Omega _{2}^{2}-\delta \Delta _{2},B=\delta \Gamma$ .

For zero ground-state linewidth (decoherence between the ground-states) $\sigma (\delta )=\sigma _{0}.g\left(\delta \right)$ where $\sigma _{0}={\frac {3}{2\pi }}\lambda ^{2}$ is the resonant cross-section, and $g(\delta )={\frac {\Gamma }{2}}{\frac {\delta B}{A^{2}+B^{2}}}$ .

There are several features of the absorption of the probe beam $\Omega _{1}$

1) Raman Resonance: $\delta =0$

This is the situation we have discussed before: EIT

2) No pump: $\Omega _{2}=0$

This is the situation of a two-level system. When the probe beam is on resonance $\Delta _{1}=0\rightarrow \delta =\Delta _{2}$ (here there is no pump beam, so $\Delta _{2}=0$ ), then the pump is completely absorbed and we have the single-photon absorption feature of width $\Gamma$ , which is a two-photon scattering process:

3) Strong pump

Here, the $|e\rangle$ and $|f\rangle$ levels are strongly coupled and, consequently, AC-Stark shifted. Since $\Omega _{1}$ is assumed to be small, the $|g\rangle$ state is effectively not altered by $\Omega _{1}$ . With this assumption, the eigenstates of the Hamiltonian consist of one ground state (same as before, $|g\rangle$ ) and two excited states which are now superpositions of the original $|f\rangle$ and $|e\rangle$ states (the superposition can be determined to first order by assuming a two-level system of $|f\rangle$ and $|e\rangle$ coupled with Rabi frequency $\Omega _{2}$ and detuning $\Delta _{2}$ ). The ground state is then coupled by the weak $\Omega _{1}$ to a narrow and a broad state

Since both of these states are coupled to the same continuum, there can be interference between the possible absorption-emission paths starting from the ground state and we can get an EIT feature on Raman resonance, as discussed in 1).

At $\delta =-{\frac {\Omega _{2}^{2}}{\Delta _{2}}}$ , we have a two-photon absorption, which is (at least) four-photon scattering process:

We can now plot the population in the excited state which gives us the absorption profile (see Lounis and Cohen-Tannoudji on Fano profiles)

File:EITFano2.jpg

For the EIT condition $\delta =0$ , there is no coupling to the excited state, and the refractive index is zero. In the vicinity of EIT, there is steep dispersion, resulting in a strong alteration of the group velocity of light $\rightarrow$ slowing and stopping light.

Slow light, adiabatic changes of velocity of light

The group velocity of light in the presence of linear dispersion ${\frac {dn}{d\omega }}$ is given by [Harris and Hau, PRL 82, 4611 (1999)]

$v_{g}={\frac {c}{1+\omega {\frac {dn}{d\omega }}}}$ for light at frequency $\omega$ .

A strong linear dispersion with positive slope near EIT then corresponds to very slow light.

As $n=1$ , the electric field is unchanged so the power per area ${\frac {P}{A}}={\frac {1}{2}}\epsilon _{o}C|E|^{2}$ also remains unchanged.

Due to slowed group velocity, the pulse is compressed in the medium. As a consequence, the energy density is increased, and the light is partly in the form of an atomic excitation (coherent superposition of the ground states, although most of the energy is exchanged to the control field).

For sufficiently small $\omega _{2}$ , the velocity of light may be very small, down to a few m/s [L.V. Hau, S.E. Harris et al., Nature 397, 594 (1999)], as observed in a BEC. Reduced group velocity can also be observed in room-temperature experiment if the setup is Doppler free (co-propagating probe and control fields $\omega _{1}$ and $\omega _{2}$ ) (otherwise only a small velocity class satisfies the two-photon resonance condition).

If we change control field adiabatically while the pulse is inside the medium, we can coherently stop light, i.e. convert it into an atomic excitation or spin wave. With the reverse process we can then convert the stored spin-wave back into the original light field. The adiabatic conversion is made possible by the finite splitting between bright and dark states. In principle, all coherence properties and other (qm) features of the light are maintained, and it is possible to store non-classical states of light by mapping photon properties one-to-one onto quantized spin waves. We will learn more about these quanta called "dark-state polaritons" once we have introduced Dicke states. Is it possible to make use of EIT for, e.g. atom detection without absorption? Answer: no improvement for such linear processes. However: improvement for non-linear processes is possible.

Superradiance

Let's assume there are two identical atoms, one in its ground and the other in its excited state. They are placed within a distance $d\ll \lambda _{eg}$ of each other. What happens?

For a single atom, the emission rate $R\left(t\right)$ at time t is $R\left(t\right)=\Gamma e^{-\Gamma t}$ (product of the spontaneous emission rate and occupation probability). Thus, the emission probability to have emitted a photon by time t is

p_{1}(t)=\int _{0}^{t}R(t')dt'=1-e^{-\Gamma t}

What happens to the two atoms case if there is only one atom in the excited state? It turns out that the correct answer is

$R_{2}\left(t\right)=\Gamma e^{-2\Gamma t}$ $p_{2}(t)=\int _{0}^{t}R_{2}(t')dt'={\frac {1}{2}}(1-e^{-2\Gamma t})$

The photon is emitted with the same initial rate, but has only probability ${\frac {1}{2}}$ of being emitted. It is saying there is still half probability for the atom remaining in the excited state. How can we understand this? The interaction Hamiltonian is:

$V=-{\vec {d}}_{1}\cdot {\vec {E}}({\vec {\gamma }},t)-{\vec {d}}_{2}\cdot {\vec {E}}({\vec {\gamma }},t)=-{\vec {D}}\cdot {\vec {E}}({\vec {\gamma }},t)$

In QED:

$V=\hbar g(\sigma _{1}^{+}+\sigma _{1}^{-})(a+a^{+})+\hbar g(\sigma _{2}^{+}+\sigma _{2}^{-})(a+a^{+})$ $=\hbar g(\sigma _{1}^{+}+\sigma _{2}^{+}+\sigma _{1}^{-}+\sigma _{2}^{-})(a+a^{+})=\hbar g(\Sigma ^{+}+\Sigma ^{-})(a+a^{+})$

with $\Sigma ^{\pm }=\Sigma _{i=1}^{2}\sigma _{i}^{\pm },{\vec {D}}=\Sigma _{i=1}^{2}{\vec {d}}_{i}$

Superradiance, continued

Now we can write the initial state as:

$|ge,0\rangle ={\frac {1}{2}}\underbrace {(|ge,0\rangle +|eg,0\rangle } _{{\sqrt {2}}|\mathrm {superradiant} \rangle }+\underbrace {|ge,0\rangle -|eg,0\rangle )} _{{\sqrt {2}}|\mathrm {subradiant} \rangle }$

where

$|\mathrm {superradiant} \rangle ={\frac {1}{\sqrt {2}}}(|ge,0\rangle +|eg,0\rangle )$

$|\mathrm {subradiant} \rangle ={\frac {1}{\sqrt {2}}}(|ge,0\rangle -|eg,0\rangle )$

and

$\langle gg,1|V|\mathrm {superradiant} \rangle ={\sqrt {2}}\hbar g;\langle gg,1|V|\mathrm {subradiant} \rangle =0$

The initial state has a 50% probability to be the sub-radiant state, hence the system has a 50% probability of not decaying. The set of four states $|gg,0\rangle ,|ge,0\rangle ,|eg,0\rangle ,|ee,0\rangle$ can be organized into a triplet and a singlet:

The state $|ge\rangle -|eg\rangle$ is "dark" in that it does not decay under the action of the Hamiltonian V. The matrix elements between the states, indicated by arrows, are expressed in units of the single atom coupling $g={\frac {1}{\hbar }}\langle e,0|V|g,1\rangle$ .

Just as we can identify the two-level system $|e\rangle ,|g\rangle$ , with a (pseudo)spin ${\frac {1}{2}}$ , we can identify the triplet and singlet states with $L=0,1$ , and write

$|L=1,M=1\rangle =|ee\rangle$

$|L=1,M=0\rangle =(|eg\rangle +|ge\rangle )/{\sqrt {2}}$

$|L=1,M=-1\rangle =|gg\rangle$

$|L=0,M=0\rangle =(|ge\rangle -|eg\rangle )/{\sqrt {2}}$

Since V conserves parity (exchange of the two atoms), there is no coupling between singlet and triplet states. (This is no longer true when we consider spatially extended samples).

Supperradiance in N atoms

First look at N spins in a magnetic field (NMR)

Dipole moment: $D=Nd$ , power radiation $\propto D^{2}=N^{2}d^{2}$ . There is N times more enhancement over N.

For N excited atoms, we usually regard the atoms as independent. Therefore, power radiation scales as N.

BUT: All two-level systems are equivalent. Which picture is correct?

Answer: There is an important distinction between sample size $\gg \lambda$ and sample size $\ll \lambda$ . For sample size $\gg \lambda$ , which is usually the case for optical transitions, the particles can be treated independently. For sample size $\ll \lambda$ , all particles interact with a common radiation field and thus cannot be treated independently.

The coherence in spontaneous emission for N (localized) atoms requires two assumptions:

1. No interaction between atoms 2. Emitted photons (NOT the atoms) are indistinguishable. The particle symmetry (Bosons, Fermions) is irrelevant.

The Dicke states, equivalent to the states obtained by summing N spin ${\frac {1}{2}}$ particles, are

Interaction with em field through $S_{+}$ , $S_{-}$

Matrix element responsible for spontaneous emission:

$\langle S,M-1|S_{-}|S,M\rangle ={\sqrt {(S-M+1)(S+M)}}$

Note matrix element only couple within one ladder. For single particle, $S=M={\frac {1}{2}}\Rightarrow \langle S,M-1|S_{-}|S,M\rangle =1$ . Rate (or intensity I) of radiation relative to a single particle: $I=(S-M+1)(S+M)$

Let's look at $S={\frac {N}{2}}$

1. Radiation rate I is the same as for N independent atoms

2. Radiation rate I $\propto N^{2}$ , N times enhancement compared with N independent atoms $\rightarrow$ characteristic for superradiant systems

3. $M=-{\frac {N}{2}}+1$ . Only one particle is excited. BUT: I=N $\Rightarrow$ N times enhancement.

The matrix element can be calculated as ${\frac {1}{\sqrt {N}}}\underbrace {(|egg\cdots g\rangle +|geg\cdots g\rangle +\cdots +|ggg\cdots e\rangle } _{Nterms})={\sqrt {N}}g$ . We can also get the matrix element by symmetry argument (should be the same as $S\rightarrow S-1$ ).

Let us look at the leftmost (symmetric) ladder. Near the middle of the Dicke-ladder, $M\simeq 0$ , the matrix element is $\langle V\rangle \simeq {\sqrt {{\frac {N}{2}}({\frac {N}{2}}+1)}}g\simeq Ng.$ The emission rate is proportional to $|\langle V\rangle |^{2}\simeq N^{2}g^{2}$ , i.e. the rate is quadratic in atom number.

Classically, that is not too surprising: we have N dipoles oscillating in phase, which corresponds to a dipole $D=Nd$ , the emission is proportional to $D^{2}=N^{2}d^{2}$ . However, the Dicke states have $\langle D\rangle =0$ and nevertheless macroscopic emission. How do we see this? In the Bloch sphere, for the angular momentum representation the coherent state $|L=N/2,M=-N/2\rangle =|g\cdots g\rangle$ corresponds to all atoms in the ground state.

A field that symmetrically couples to all atoms (e.g. ${\frac {\pi }{2}},\pi$ pulse) acts only within the completely symmetric Hilbert space $L=N/2$ . This space consists of states like $(\cos \theta |e\rangle +\sin \theta e^{i\phi }|g\rangle )^{N}$ , corresponding to rotations of the state $|g\cdots g\rangle$ around some axis on the Bloch sphere.

The states obtained by rotations of the state $|g\cdots g\rangle$ by symmetric operations that act on all individual atoms independently, i.e. of the form $|g\rangle \rightarrow \cos \theta |e\rangle +e^{i\phi }\sin \theta |g\rangle$ , are called coherent spin states (CSS). They are represented by a vector on the Bloch sphere with uncertainties ${\sqrt {\frac {L}{2}}}$ in directions perpendicular to the Bloch vector.

If we prepare a system in the CSS corresponding to a slight angle away form $\theta =0$ near $|e\cdots e\rangle =|L=N/2,M=N/2\rangle$ , then classically it will obey the eqs of motion of an inverted pendulum, and fall down along the Bloch sphere. (This can be shown using the classical analogy with a field.)

Question1: So what happens if we prepare the state $|M=+L\rangle =|e\cdots e\rangle$ ? Does it:

a. evolve down along the Dicke ladder maintaining $\langle D\rangle =0$ (but $\langle D^{2}\rangle \neq 0$ )?

b. fall like a Bloch vector along some angle chosen by vacuum fluctuations?

Answer: there is no way of telling unless you prepare a specific experiment. If we detect (with unity quantum efficiency) the emitted photons, then each detection projects the system one step down along the Dicke ladder, and $\langle D\rangle =0$ .

If we measure the phase of the emitted light, say with some heterodyne technique, then we find that the system evolves as a Bloch state.

Question2: Is there enhanced induced emission or absorption?

Answer:No. initial state $(|g\rangle )^{N}$ , single particle $|g\rangle \rightarrow |\psi _{1}(t)\rangle$ , N particles $(|g\rangle )^{N}\rightarrow (|\psi _{1}(t)\rangle )^{N}$ . Consequently, it takes exactly half a Rabi period to completely invert the population as for a single atom. There are N Dicke steps with N times larger matrix elements. In contrast, for spontaneous emission, there are N Dicke steps, with $N^{2}$ times larger matrix elements $\Rightarrow$ N times faster.

Dicke states of extended samples

Consider an elongated atomic sample

such that a preferential mode (along x) is defined. Emission into solid angle ${\frac {\lambda ^{2}}{A}}$ can be coherent. Thus, the total radiation intensity is enhanced by a factor of about ${\frac {N\lambda ^{2}}{A}}=nAL{\frac {\lambda ^{2}}{A}}=n\lambda ^{2}L$ . This is analogous to optical amplification gain cross section $\lambda ^{2}$ . Formally, we can define Dicke states with respect to the preferred mode as

$|L,M=-L\rangle =|g\cdots g\rangle$

$|L,M=-L+1\rangle ={\frac {1}{\sqrt {N}}}(e^{ikx_{1}}|eg\cdots g\rangle +e^{ikx_{2}}|geg\cdots \rangle +\cdots +e^{ikx_{N}}|g\cdots ge\rangle )$

$|L,M=-L+2\rangle ={\frac {\sqrt {2}}{\sqrt {N(N-1)}}}(e^{ikx_{1}}e^{ikx_{2}}|eeg\cdots g\rangle +e^{ikx_{1}}e^{ikx_{3}}|egeg\cdots \rangle +\cdots )$

etc.

Then one can easily see that the phase factors are such that the interaction Hamiltonian

$V=\Sigma _{i}{\vec {d_{i}}}\cdot {\vec {E}}({\vec {x_{i}}})=\Sigma _{i}{\vec {d}}\cdot {\vec {E}}_{0}e^{i\kappa x_{i}}$

is such that the Dicke ladder has the same couplings as before, i.e. superradiance occurs. However, emission along a direction other than the preferred mode now leads to diagonal couplings between the Dicke ladders , since emission along some other direction with operator $e^{i{\vec {k}}\cdot {\vec {r}}}$ does not preserve the symmetry of the state with respect to permutations of the atoms. However, if the atom number along the preferred direction is large enough, superradiance still occurs. The condition for $A\ll \lambda ^{2}$ is $N\geq 2$ , but for $A>\lambda ^{2}$ the condition is ${\frac {N\lambda ^{2}}{A}}>1$ . This is exactly the condition for sufficient optical gain in an inverted system for optical amplification (lasing) to occur, since $\lambda ^{2}$ is the stimulated emission cross section for an atom in $|e>$ .

Observation in a BEC, in multimode optical cavities.

Oscillating and overdamped regimes of superradiance

The photon leaves the sample in a time ${\frac {L}{c}}$ . If ${\sqrt {N}}g<{\frac {c}{L}}$ , then the damping is faster than Rabi flopping, and we are in the rate equation limit where the emission proceeds as ${\frac {({\sqrt {N}}g)^{2}}{c/L}}={\frac {Ng^{2}L}{c}}$ , rather than as emission by independent atoms that would decay as ${\frac {g^{2}}{c/L}}$ . If ${\sqrt {N}}g>{\frac {c}{L}}$ , then Rabi flopping occurs during the decay.

Note: $\Gamma =g^{2}L/C$ .

Raman Superradiance

In the limit of large detuning and low saturation $\Omega \ll \Delta$ , we can eliminate the excited state by using the dressed atoms' picture. The dressing beam $\Omega$ is making a two-photon resonance from $|g_{1}\rangle$ to $|g_{2}\rangle$ . From another picture, it is also mixing the two levels $|e\rangle$ and $|g_{2}\rangle$ . If we eliminate the excited state, we will get a effective two level system.

For the mixing level $|g_{2}\rangle$ , the scattering rate will be $\Gamma _{sc}={\frac {\Omega ^{2}}{\Delta ^{2}}}{\frac {\Gamma }{2}}$ .

Now we find We can adjust the linewidth $\Gamma _{sc}$ via $\Omega$ for the effective excited state $|g_{2}\rangle$ .

Storing light, catching photons

When we consider a quantized field on the $|g_{1}\rangle \rightarrow |e\rangle$ transition and a classical control beam connecting $|g_{2}\rangle$ and $|e\rangle$ , there is a family of dark states for the collective three-levels systems, corresponding to $n=0,1,2,\cdots$ excitations in different spin manifolds for a N photons input state.

$|D,n\rangle =\Sigma _{k=0}^{n}{\sqrt {\frac {n!}{k!(n-k)!}}}{\frac {(-g)^{k}N^{\frac {k}{2}}\Omega ^{n-k}}{(Ng^{2}+\Omega ^{2})^{\frac {n}{2}}}}|n-k\rangle _{\mathrm {photons} }|L={\frac {N}{2}},M=-L+k\rangle$

(Lukin, Yelin, and Fleischhauer PRL 84, 4232 (2000)).

When $\Omega ^{2}\gg Ng^{2}$ , these states are purely photonic. When $\Omega ^{2}\ll Ng^{2}$ , these states are purely atomic excitations.

$\Omega ^{2}\gg Ng^{2}:|D,n\rangle \rightarrow |n\rangle _{\mathrm {photons} }|L,M=-L\rangle _{\mathrm {atoms} }$

$\Omega ^{2}\ll Ng^{2}:|0>_{\mathrm {photons} }|L,M=-L+n\rangle _{\mathrm {atoms} }$

In general, these excitations $n=0,1,2,\cdots$ are called dark state polaritons. They are a mixture of photonic excitations and spin-wave excitations.

By adiabatically changing $\Omega \rightarrow 0$ after the pulse has entered the medium, we can map any photonic state $|\psi \rangle _{\mathrm {photon} }=\Sigma c_{i}|i\rangle _{\mathrm {photon} }$ onto a spin wave, store it and map it back onto a light-field by turning on the coupling laser $\Omega$ again.

Notes

Old Coherence Page

@@ Line 1: / Line 1: @@
-We speak of coherence if there exist well defined phases between two or more
+== Introduction ==
-amplitudes that can interfere.  These can be, e.g., the relative phase of the
-electric field in two arms of an interferometer, the relative phase of two or
+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. <math> |\langle \phi | \psi \rangle|^2 </math>.
-more states within one atom, or the relative phase of oscillating dipole moments
-in different atoms.  Coherence is often a measurement tool in that the relative
+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. <math> \Omega_{\text{Rabi}} \gg \Gamma </math>. 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 <math> \Omega_{\text{Rabi}} </math> (e.g. a strong laser).
-phase is the time integral over the energy difference between the states.  For
-instance, if the atomic states have different magnetic moments, coherence
+Here, we explore many examples where coherence and interference play an important role.
-between them provides a very sensitive measurement tool for magnetic field, or
-if the states have different spatial wavefunctions, the relative phase is a
-sensitive measure of the gravitational energy difference.  In atomic clocks,
-coherence allows one to transform as energy difference between two internal
-atomic states into a frequency and time standard.
 <categorytree mode=pages style="float:right; clear:right; margin-left:1ex; border:1px solid gray; padding:0.7ex; background-color:white;" hideprefix=auto>8.421</categorytree>
+== 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 <math> \sum_{\text{modes}} \frac{\omega_{R}}{2} (\sigma^{+} a + \sigma^{-} a^{+}) </math>, 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 ==
-A two-level atom that has been prepared by a <math>\frac{\pi}{2}</math> pulse in a
-superposition <math>\frac{1}{\sqrt{2}}(|g\rangle+|e\rangle)</math> can be viewed as
+===Measuring Coherence===
-exhibiting coherence, since the phase between <math>|e\rangle</math> and <math>|g\rangle</math> is
+A two-level atom can be prepared by a <math>\pi/2</math> pulse in a
+superposition <math>1/\sqrt{2}(|g\rangle+e^{-i\phi_{0}}|e\rangle) \otimes |0\rangle </math>, where <math> |0\rangle </math> 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 <math> \phi_{0} </math> between <math>|e\rangle</math> and <math>|g\rangle</math> is
 well defined, and the system will evolve coherently as
-<math>\frac{1}{\sqrt{2}}(|g\rangle+e^{-i\omega_ot}|e\rangle)</math> for times
+<math>1/\sqrt{2}(|g\rangle+e^{-i(\omega_ot+\phi_{0})}|e\rangle) \otimes |0\rangle </math>. This occurs for times
-<math>t\leq\frac{1}{\Gamma}</math>, where <math>\Gamma</math> is the decay rate constant for the
+<math>t\leq\ 1/\omega_{1}</math>, where <math>\omega_{1} </math> is the vacuum Rabi oscillation frequency, after which <math> |e\rangle \otimes |0\rangle \longrightarrow |g\rangle \otimes |1\rangle </math>. After this "spontaneous emission" has occurred the state of the system is <math> |g\rangle \otimes (1/\sqrt{2}(|0\rangle+e^{-i(\omega_ot+\phi_{0})}|1\rangle) </math>, and the quantum state of the atom has been mapped onto the photon field.
-excited state. Figure \ref{fig:single-atom-coherence} displays a conceptual
+The figure below displays a conceptual
-experiment that can be used to test this.
+experiment that can be used to test this, where an interferometer is used to perform an optical [http://en.wikipedia.org/wiki/Homodyne_detection homodyne detection] of the light emitted by the atom and thereby obtain its phase (relative to that of the excitation light).
-\begin{figure}
-\centering
+[[Image:coherence-single-atom-coherence-experiment.png|thumb|400px|center|Measurement of definite phase for light emitted by a two-level atom
-::[[Image:coherence-single-atom-coherence-experiment.png|thumb|400px|none|]]
-\caption{Measurement of definite phase for light emitted by a two-level atom
 prepared with a <math>\pi/2</math> pulse.  The laser light is sent through both arms of an
 interferometer; a switch in one arm selects a <math>\pi/2</math> pulse of light from the
-laser with which to excite the atom.  The light the atomic dipole emits is then
+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 <math>\pi/2</math> pulse.}
+of the exciting <math>\pi/2</math> pulse.]]
-\end{figure}
 What about an atom prepared by a <math>\pi</math> pulse in <math>|e\rangle</math>? There is no
 coherence at <math>t=0</math>, since the atom is in a single state, but what about
-<math>t=\frac{1}{\frac{\Gamma}{2}}</math>?  Then the atom is in a superposition of states
+<math>t=1/(\omega_{1}/2)</math>?  Then the atom is in a superposition of states
 <math>\sim|g\rangle+e^{-i\omega_0t+\phi_0}|e\rangle</math>.  Obviously some phase must
 exist, because otherwise no dipole moment <math> {\bf{d}} (t)=\langle
-e(t)|q {\bf{r}} |g(t)\rangle</math> exists that can emit (<math>\int^{2\pi}_{0}d\phi\langle
+e(t)|q {\bf{r}} |g(t)\rangle</math> exists that can emit, but the phase <math>\phi_0</math> is completely
-e|e^{i\phi}q {\bf{r}} |g\rangle=0</math>), but the phase <math>\phi_0</math> 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 (<math>\int^{2\pi}_{0}d\phi\langle
-unpredictable, so the experiment pictured above (or an emsemble average, as in
+e|e^{i\phi}q {\bf{r}} |g\rangle=0</math>).  We
-Figure \ref{fig:ensemble-average-coherence}) would yield no definite phase.  We
 conclude that an atom prepared in <math>|e\rangle</math> does not exhibit coherence.
-\begin{figure}
-\centering
+[[Image:coherence-ensemble-average-coherence.png|thumb|400px|center|Ensemble average of the phase measurement.]]
-::[[Image:coherence-ensemble-average-coherence.png|thumb|400px|none|]]
-\caption{Ensemble average of the phase measurement.}
-\end{figure}
+The ensemble average as in the figure above (parallel setups) or time average (repeated experiment at
-The ensemble average (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 <math>\langle d(t)\rangle=0</math> is zero at all times.  What
+value of the dipole moment <math>\langle d(t)\rangle=0</math> is zero at all times (but <math> \langle d^{2} \rangle \neq 0 </math>!).  What
-is the origin of uncertain phase <math>\phi_o</math>? Vacuum fluctuations.  What then
+is the origin of this uncertain phase <math>\phi_o</math>? 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 the chapter.
+will be covered later in this chapter.
-== Precession of a spin in a magnetic field ==
+=== 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 <math>|\psi\rangle = C_g |g\rangle + C_e |e\rangle</math>.
+Then, the coherence between <math>|e\rangle</math> and <math>|g\rangle</math> is maximum for <math>C_ e=C_ g=1/\sqrt {2}</math>, i.e. with a <math>\pi/2</math> pulse. Indeed, recall that the coherences are the off-diagonal elements of the density matrix, <math>\rho_{ab}</math>. For a pure state, they are <math>C_g C_e^{*}</math> 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: <math>|g,1\rangle</math> and <math>|e,0\rangle</math>. Thus, a <math>\pi/2</math> pulse also maximizes the coherence <math>|g,1\rangle</math> and <math>|e,0\rangle</math>.
+Similarly, consider a coherent light which is very weak. Monochromatic, coherent light is represented by a coherent state<math>|\alpha ></math> that has a Poissonian distribution of photon numbers:
+:<math>|\alpha \rangle=e^{-\frac{1}{2}|\alpha|^{2}}  \sum_{n = 0}^{\infty } \frac{ \alpha^{n}}{\sqrt{n+1}} |n\rangle</math>
+For <math>|\alpha | \ll 1 </math>, the population of the states with <math>n > 1</math> is negligible, and the atom prepared in a state <math>|g>+\epsilon |e></math> with <math>|\epsilon | \ll 1</math> emits a coherent state of light, in agreement with what is expected for small saturation (see [[Dressed atom approach| 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 [[Solutions of the optical Bloch equations| 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
-<math>|x\rangle=\frac{1}{\sqrt{2}}(|+z\rangle+|-z\rangle)</math>. In a magnetic field
+<math>|x\rangle= 1/\sqrt{2} (|+z\rangle+|-z\rangle)</math>. In a magnetic field (see [[Resonances#Magnetic Moment in a Static Field| earlier section]]),
-<math>|\psi(t)\rangle=\frac{1}{\sqrt{2}}(e^{-i\omega_L\frac{t}{2}}|+z\rangle+e^{i\omega_L\frac{t}{2}}|-z\rangle)</math>,
+<math>|\psi(t)\rangle=1/\sqrt{2}(e^{-i\omega_L\frac{t}{2}}|+z\rangle+e^{i\omega_L\frac{t}{2}}|-z\rangle)</math>, corresponding to precession in the x-y plane.
-so the precession is due to a coherence between the <math>|\pm z\rangle</math> components
+In other words, the precession is due to a coherence between the <math>|\pm z\rangle</math> components
 of the spin.  If no coherence existed, the spin would be in a statistical
-mixture of <math>|+z\rangle</math> and <math>|-z\rangle</math>.
+mixture of <math>|+z\rangle</math> and <math>|-z\rangle</math>, exhibiting no measurable precession.
 In the density matrix formalism,
 :<math>
-\rho=\left( \begin{array}{cc}
+\rho=|\psi(t)\rangle \langle \psi(t)|= \left( \begin{array}{cc}
 \frac{1}{2} & \frac{1}{2}e^{-i\omega_Lt}  \\
 \frac{1}{2}e^{i\omega_Lt} & \frac{1}{2}  \\
 \end{array} \right)
 </math>
-in the z basis <math>|+z\rangle=\left(\begin{array}{cc}1\\0\end{array}\right), |-z\rangle=\left(\begin{array}{cc}0\\1\end{array}\right)</math>.\\The expectation value of <math>\hat\sigma_x=\left(\begin{array}{cc}0&1\\1&0\end{array}\right)</math>,
+in the z basis <math>|+z\rangle=\left(\begin{array}{cc}1\\0\end{array}\right), |-z\rangle=\left(\begin{array}{cc}0\\1\end{array}\right)</math>.
+The expectation value of <math>\hat\sigma_x=\left(\begin{array}{cc}0&1\\1&0\end{array}\right)</math> is
 :<math>
 \langle\hat\sigma_x\rangle= Tr [\rho\hat\sigma_x]= Tr  \left(\begin{array}{cc}\frac{1}{2}e^{-i\omega_Lt}&\frac{1}{2}\\\frac{1}{2}&\frac{1}{2}e^{i\omega_Lt}\end{array}\right)=\cos\omega_Lt.
 </math>
-If the coherences (off-diagonal elements of <math>\hat\rho</math>) were smaller, <math>\hat\sigma_x</math> would be smaller. For a statistical mixture of <math>|+z\rangle</math> and <math>|-z\rangle</math>, <math>\rho=\left(\begin{array}{cc}\frac{1}{2}&0\\0&\frac{1}{2}\end{array}\right)</math> and <math>\langle\hat\sigma_x\rangle=0</math>.
+If the coherences (off-diagonal elements of <math>\hat\rho</math>) were smaller, <math>\langle\hat\sigma_x\rangle</math> would be smaller. For a statistical mixture of <math>|+z\rangle</math> and <math>|-z\rangle</math>, <math>\rho=\left(\begin{array}{cc}\frac{1}{2}&0\\0&\frac{1}{2}\end{array}\right)</math> and <math>\langle\hat\sigma_x\rangle=0</math>.
-== The Stern-Gerlach experiment and spatial loss of coherence ==
-\begin{figure}
+=== The Stern-Gerlach experiment and (ir)reversible spatial loss of coherence ===
-\centering
+[[Image:coherence-Stern-Gerlach.png|thumb|400px|Stern-Gerlach experiment. Where, in the magnet or outside, does the projection onto <math>|\pm z\rangle</math> occur?]]
-::[[Image:coherence-Stern-Gerlach.png|thumb|400px|none|]]
-\caption{Stern-Gerlach experiment. Where in the magnet (or outside) does the projection onto <math>|\pm z\rangle</math> occur?}
+[[Image:coherence-stern-gerlach-wavefunctions.png|thumb|400px|Spatial wave function and corresponding spin density matrix in the Stern-Gerlach experiment.]]
-\end{figure}
 In the Stern-Gerlach experiment a particle initially spin-polarized along
 <math>|x\rangle</math> has equal probability of following either the <math>|+z\rangle</math>
@@ Line 92: / Line 123: @@
 So initially the particle is described by a density matrix for a pure state,
 :<math>
-\rho_{in}=\left(\begin{array}{cc}\frac{1}{2}&\frac{1}{2}\\\frac{1}{2}&\frac{1}{2}\end{array}\right),
+\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),
 </math>
 after passing the Stern-Gerlach apparatus (inhomogeneous magnetic field) the
@@ Line 99: / Line 130: @@
 \rho_{out}=\left(\begin{array}{cc}\frac{1}{2}&0\\0&\frac{1}{2}\end{array}\right)
 </math>
-with no intereference possible between the two states.
+with no interference possible between the two states.
 Why?  Because describing the full quantum state of the particle also requires
-acocunting for its spatial wavefunction.  The density matrix above does not
+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
 :<math>
-|\psi\rangle=|x\rangle\otimes|\psi_{spat}\rangle=\frac{1}{\sqrt{2}}\left(\begin{array}{c}\psi_{in}( {\bf{r}} )\\\psi_{in}( {\bf{r}} )\end{array}\right)
+|\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)
 </math>
 with <math>\psi_{+z}( {\bf{r}} )=\psi_{-z}( {\bf{r}} )=\psi_{in}( {\bf{r}} )</math>,
@@ Line 114: / Line 145: @@
 differently because there is a different potential energy seen by the two spin
 states <math>|\pm z\rangle</math>:
-:<math>
-|\psi(t)\rangle=\frac{1}{\sqrt{2}}\left(\begin{array}{c}\psi_{+z}( {\bf{r}} ,t)\\\psi_{-z}( {\bf{r}} ,t)\end{array}\right).
+<math> |\psi(t)\rangle=\frac{1}{\sqrt{2}}\left(\begin{array}{c}\psi_{+z}( {\bf{r}} ,t)\\\psi_{-z}( {\bf{r}} ,t)\end{array}\right). </math>
-</math>
-\begin{figure}
+Using the density matrix formalism:
-\centering
-::[[Image:coherence-stern-gerlach-wavefunctions.png|thumb|400px|none|]]
+<math> \rho(t) =|\psi(t)\rangle \langle\psi(t)|=  \frac{1}{2} \left(\begin{array}{cc} |\psi_{+z}( {\bf{r}} ,t)|^{2} & \psi^{\dagger}_{+z}( {\bf{r}} ,t)\psi_{-z}( {\bf{r}} ,t) \\\ \psi_{+z}( {\bf{r}} ,t)\psi^{\dagger}_{-z}( {\bf{r}} ,t) & |\psi_{-z}( {\bf{r}} ,t)|^{2} \end{array}\right) </math>
-\caption{Spatial wave function and corresponding spin density matrix in the Stern-Gerlach experiment.}
-\end{figure}
+And so the spin coherence as earlier defined is simply:
+<math> \langle \hat \sigma_{x} \rangle = Tr(\rho(t) \hat \sigma_{x}) = \int d\bf{r} \frac{1}{2} (\psi^{\dagger}_{+z}( {\bf{r}} ,t)\psi_{-z}( {\bf{r}} ,t) + \psi_{+z}( {\bf{r}} ,t)\psi^{\dagger}_{-z}( {\bf{r}} ,t)) </math>
+Which is indeed zero in the absence of spatial overlap of the <math> |\pm z\rangle </math> components.
 The coherence (interference) between <math>|+z\rangle</math> and <math>|-z\rangle</math> components to
-form <math>|x\rangle</math> exists only in the region where there is at least partial
+form <math>|x\rangle</math> thus exists only in the region where there is at least partial
 overlap between the two wavefunctions <math>\psi_{+z}( {\bf{r}} ),\psi_{-z}( {\bf{r}} )</math>.
 When the wavefunctions do not overlap, there is no significance to a relative
@@ Line 143: / Line 179: @@
 meter-variable entanglement is still reversible, and a "measurement" has not
 been made.
-== Quantum Beats ==
+=== Quantum Beats ===
+[[Image:coherence-QB-levels.png|thumb|200px|'''Quantum Beat Levels''' Multiple levels within energy <math>\hbar\Delta</math> from ground state, <math>\Delta>\Gamma,\Gamma',\Gamma'',\ldots</math>.]]
 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.
-\begin{figure}
-\centering
-::[[Image:coherence-QB-levels.png|thumb|400px|none|]]
-\caption{Multiple levels within energy <math>\hbar\Delta</math> from ground state, <math>\Delta>\Gamma,\Gamma'</math>,\ldots}
-\end{figure}
+Consider the scenario of the figure on the right (Quantum Beat Levels), where we have multiple
-Consider the scenario of Figure \ref{fig:qb-levels}, where we have multiple
 excited levels in a narrow energy interval <math>\hbar\Delta</math>, all decaying to a
 common ground state.  If we excite with a pulse of duration <math>\Delta
-t\ll\frac{1}{\Delta}</math>, we cannot resolve the levels, and they will be populated
+t\ll1/\Delta</math> (or a broadband source), we cannot resolve the levels, and they will be populated
 according to the coupling strength to the ground state <math>|g\rangle</math> for the given
 excitation method:
@@ Line 168: / Line 202: @@
 |\psi(t)\rangle=\Sigma  c_i e^{-i\omega_it}|e^{(i)}\rangle.
 </math>
-It follows that, in directions where the radiation from the levels <math>|e^{(i)}\rangle</math> interferes, there will be oscillating terms at frequencies <math>\omega_i-\omega_j</math> on top of the excited state decay.
+It follows that, in directions where the radiation from levels <math>|e^{(i)}\rangle</math> and <math>|e^{(j)}\rangle</math> interferes, there will be oscillating terms at frequencies <math>\omega_i-\omega_j</math> on top of the excited state decay, i.e. the so-called "quantum beats".
-\begin{figure}
-\centering
-::[[Image:coherence-QB.png|thumb|400px|none|]]
-\caption{Quantum beats}
-\end{figure}
 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), and no coherence between
+states (definite excitation phase between them, i.e. see <math>
+|\psi(t)\rangle </math> above ), while no coherence between
 <math>|e^{(i)}\rangle</math> and <math>|g\rangle</math> exists initially.  Of course, as the atom
-decays, coherence between <math>|e^{(i)}\rangle</math> and <math>|g\rangle</math> (e.g. dipole
+decays, coherences between <math>|e^{(i)}\rangle</math> and <math>|g\rangle</math> (e.g. dipole
 moments) build up, and the coherence between the emitted fields of the different
-dipoles gives rise to the observed effect.  Figures \ref{fig:qb-ideal} and
+dipoles gives rise to the observed effect. The two following figures show respectively an idealized quantum beat signal and real
-\ref{fig:qb-data} show respectively an idealized quantum beat signal and real
 data from an experimental demonstration of the technique.
-\begin{figure}
-\centering
-::[[Image:coherence-QB-data.png|thumb|400px|none|]]
-\caption{Schematic level diagrams and observed quantum beats of <math>^4He  3^3P</math> at
-keV/atom; H, n=3, and H, n=4 at 133 keV/atom. \cite{Andra1970}}
-== Clarification on coherence and dipole moment ==
-Consider the coherence of the atom after coherent excitation with a short pulse (shorter than emission rate). Let the state of the atom be <math>|\psi> = C_g |g> + C_e |e></math>.
+{|
-Then, the coherence between <math>|e></math> and <math>|g></math> is maximum for <math>C_ e=C_ g=\frac{1}{\sqrt {2}}</math>, i.e. with <math>\frac{\pi }{2}</math> pulse. (Coherence is <math>\rho_{ab}</math> in the density matrix. For a pure state, it is <math>C_g C_e</math>). Now, let us consider a system with the atom and (external) EM mode. We consider the case where there is only a single EM mode coupled to the atom (ex, an atom strongly coupled to a cavity). Then, emission couples atomic states with photon number states: <math>|g,1></math> and <math>|e,0></math>. Thus, a <math>\frac{\pi }{2}</math> pulse also maximizes the coherence <math>|g,1></math> and <math>|e,0></math>.
+|valign="top"|[[Image:coherence-QB.png|thumb|left|baseline|400px|Idealized quantum beat signal.]]
+|valign="top"|[[Image:coherence-QB-data.png|thumb|right|baseline|400px|Schematic level diagrams and observed quantum beats of <math>^4He  3^3P</math> 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 <math> t=0 </math>, but only start detection after a time <math> t_{0} \gg 1/\Gamma </math>, can one obtain a spectral resolution narrower than <math> \Gamma </math>?
+Our signal is:
+:<math> S(t) = (1+\alpha \cos (\omega_{0} t))e^{-\Gamma t} </math>,
+whose Fourier Transform is a Lorentzian
+:<math> L(x) = \frac{1}{1+x^{2}} </math>,
+where <math> x=\frac{\omega-\omega_{0}}{\Gamma} </math>.
+Starting the measurement at <math> t_{0} </math> is equivalent to the spectrum:
+:<math> S_{0}(\omega) = \int_{t_{0}}^{\infty} S(t) e^{-i\omega t} dt </math>
+Let <math> T=t_{0} \Gamma </math>, then:
+:<math> \Re(S_{0}(\omega)) = F(x) = L(x) e^{-T} (\cos(xT) - x \sin(xT)) </math>
+:<math> \Im(S_{0}(\omega)) = G(x) = L(x) e^{-T} (\sin(xT) - x \cos(xT)) </math>
+Of course if the absolute magnitude of the spectrum is considered, the Lorentzian part is independent of <math> T </math>:
+:<math> |F(x)+iG(x)|^{2} = F(x)^{2} + G(x)^{2} = e^{-2T} L(x) </math>
+However <math> F(x) </math> at large <math> x </math> has oscillations and a narrow central peak of order <math> 1/T </math>. Sub-natural linewidth spectroscopy is possible!
+'''Note''': if <math> S(t) = (1+\alpha \cos (\omega_{0} t + \phi))e^{-\Gamma t} </math>, and <math> \phi </math> is random, then one can only measure <math> |F+iG|^{2} </math>. Thus sub-natural spectroscopy requires information on the phase of the signal at <math> t=0 </math>.
+== 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 <math>|\mathrm{internal}\rangle|\mathrm{external}\rangle</math> states. The radiation can then impart momentum, known as recoil momentum.
+There are three basic configurations: V-type, <math>\Lambda</math>-type, and Ladder type.
+[[Image:VLL.jpg|center|800px]]
+Here we focus on the <math>\Lambda</math>-type. We can think of <math>|g_1\rangle ,|g_2\rangle </math> 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 <math>|e\rangle</math>. The coupling strengths are the Rabi frequencies <math>\Omega_1 = \frac{d_1 \cdot E_1}{\hbar}</math> and <math>\Omega_2 = \frac{d_2 \cdot E_2}{\hbar}</math> (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. <math>|g_1\rangle</math> or <math>|g_2\rangle</math>). 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 <math>\Lambda</math> system by turning on only one laser beam (<math>\Omega_1\neq 0, \Omega_2=0</math>) which transfers all the atoms into the uncoupled state (in this case <math>|g_2\rangle</math>).
+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.
+[[Image:OP1.png|center|800px]]
+=== Dark State (On Resonant Case) ===
+Assume the semiclassical Hamiltonian with the rotating wave approximation for the system.
+:<math>
+H= \hbar \omega _{1e}|e\rangle \langle e| +\hbar \delta |g2\rangle \langle g2|
+ </math>
+:<math>
++\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)
+ </math>
+[[Image:Lambda_sys.png|center|400px]]
+The second line is the interaction term.  Define this as <math>\hat{V}  </math>.  Be careful about the notation in <math>\omega  </math> s. <math>\omega </math>s are for energy scale.  <math>\omega _1e  </math> and <math>\omega _2e  </math> are the energy difference of three states.  <math>\omega _{1}  </math> and <math>\omega _{2}  </math> are the frequency of two lasers.    <math> \Omega </math>s show the coupling strength and <math> \Omega_1 </math> and <math> \Omega_2 </math> correspond to the coupling of <math> |g1\rangle </math> and <math> |g2\rangle </math> 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.
+:<math>\begin{pmatrix}
+& \frac{\Omega_1}{2} & 0 \\
+      \frac{\Omega_1}{2} & 0 & \frac{\Omega_2}{2}\\
+& \frac{\Omega_2}{2} & 0 \\
+\end{pmatrix}</math>
+Diagonalizing this, you get the energy eigenvalues <math> 0 </math>, <math> -\hbar \sqrt{\Omega_1^2+\Omega_2^2} </math> and <math> \hbar \left( \omega_{1e}+\sqrt{\Omega_1^2+\Omega_2^2} \right) </math> and corresponding eigenstates <math> \frac{\Omega _2}{\sqrt{\Omega _1^2+\Omega _2^2}} |g1 \rangle - \frac{\Omega _1}{\sqrt{\Omega _1^2+\Omega _2^2}} |g2 \rangle </math>, <math>-\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 </math> and <math> \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 </math>  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
+:<math>
+\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
+ </math>
+For <math>\Omega _1\ll \Omega _2  </math>, the dark state is <math>|g1 \rangle  </math>.  Dark state is predominantly the state with weaker coupling.  The orthogonal superposition of two stable states is the bright state.
+:<math>
+|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
+ </math>
+=== 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 <math> \Omega_1 </math> and <math> \Omega_2 </math>, you can make the arbitrary superposition of two stable states.
+[[Image:CoherentPopulationTrapping2.png|center|400px]]
+=== Effective 2-level System: Dark State (Off Resonant Case) ===
+(Here we follow  [http://atomoptics.uoregon.edu/~dsteck/teaching/quantum-optics/ D. A. Steck, Quantum and Atom Optics, Chapter 6.])
+[[Image:Raman1.jpg|center|800px|]]
+Consider the <math>\Lambda</math> configuration shown above and let's ignore the external degrees of freedom for now. If <math> \Delta \gg \Omega, \Gamma </math>, we can treat the 3-level system as an effective two level system. <math>\Delta</math> 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 <math> |g_1\rangle \longleftrightarrow |e\rangle </math> and <math>|g_2\rangle \longleftrightarrow |e\rangle </math> 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:
+:<math>
+|\Psi\rangle=\tilde{c}_1 |g_1\rangle + c_e | e \rangle + \tilde{c}_2 |g_2\rangle
+</math>
+Here <math> \tilde {c}_1=c_1 e^{- i\omega_1 t} </math> and <math> \tilde{c}_2=c_2 e^{- i\omega_2 t} </math> are the slowly-varying amplitudes.
+'''For simplicity''', we set: <math>\Delta_1=\Delta_2=\Delta</math> (so that we are on two-photon resonance), <math>\delta=0</math> (so that the two ground states are degenerate), and we pick the zero of the energy to be at <math> |g\rangle </math>. Then, in the RWA and in the rotating frame we just defined, and in the basis <math>(|g_1\rangle, |e\rangle, |g_2\rangle)</math>, the Hamiltonian is:
+:<math>\begin{pmatrix}
+& \frac{\Omega_1}{2} & 0 \\
+      \frac{\Omega_1}{2} & \Delta & \frac{\Omega_2}{2}\\
+& \frac{\Omega_2}{2} & 0 \\
+\end{pmatrix}</math>
+From here, we can write the Schrodinger equation for the three amplitudes:
+:<math>\begin{align}
+& 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{align}</math>
+We can now assume that the excited state amplitude evolves at a frequency determined by the detuning <math>\Delta</math>. But since we want <math>\Delta</math> to be large compared to the timescale of the dynamics of the system (which is set by <math>\Omega_1, \Omega_2 </math>), we can neglect its time variation: <math>\frac{\partial}{\partial t} c_e \approx 0 </math>. We can then solve the system of equations above by eliminating <math>c_e</math> to get (now in the basis <math>(|g_1\rangle |g_2\rangle)</math>)
+:<math>
+\begin{pmatrix}
+      \frac{\Omega^2_1}{4 \Delta} & \frac{\Omega_1 \Omega_2}{4 \Delta} \\
+      \frac{\Omega_1 \Omega_2}{4 \Delta} & \frac{\Omega^2_2}{4 \Delta}\\
+\end{pmatrix}
+</math>
+We recognize the off-diagonal entries as the two-photon Rabi frequency. The eigenenergies and eigenstates are:
+:<math>
+\begin{align}
+E_D=0 &\longrightarrow |D\rangle = -\frac{\Omega_2}{\sqrt{\Omega^2_1+\Omega^2_2}}|g_1\rangle +\frac{\Omega_1}{\sqrt{\Omega^2_1+\Omega^2_2}} |g_2\rangle \\
+E_B=\frac{\Omega^2_1+\Omega^2_2}{4 \Delta} &\longrightarrow |B\rangle = \frac{\Omega_1}{\sqrt{\Omega^2_1+\Omega^2_2}}|g_1\rangle +\frac{\Omega_2}{\sqrt{\Omega^2_2+\Omega^2_2}} |g_2\rangle
+\end{align}
+</math>
+The dark state <math>|D\rangle</math> is the coherent superposition of uncoupled states which does not interact with the light.
+=== External states: VSCPT ===
+[[Image:vscpt2.png|center|800px]]
+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 <math>|internal\rangle |external\rangle</math>, 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 (<math>v \pm \Delta v</math>). 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 <math>\Delta\omega</math> on resonance with the 1-photon transition from <math>|g\rangle</math> to <math>|e\rangle</math>. Let the atoms start in <math>|g\rangle</math> with momentum <math>\vec{p}_1</math> and let their momentum after interacting with the laser beams be <math>p_2</math>. Let's neglect spontaneous emission for now.
+From energy and momentum conservation (in 1D):
+:<math>
+\begin{align}
+\hbar k + p_1 = -\hbar k + p_2 \\
+\hbar \omega + \frac{p^2_1}{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{align}
+</math>
+So that only atoms with initial momentum <math>p_1 \pm </math> will satisfy the Raman resonance condition and will interact with the two beams and can be pumped into a dark state. \\
+We can analyze the 3-level velocity-dependent system in the same way we analyzed the internal-state 3-level system. Let's assume for simplicity that <math>\Delta \omega = 0</math>. The 3 levels are <math>|g, \hbar k\rangle, |e,0\rangle, |g,-\hbar k\rangle</math>. The dark state is:
+:<math>|D\rangle = \frac{1}{\sqrt{2}} \left( c_1|g_1,-\hbar k\rangle + c_2|g_2,+\hbar k \rangle\right)</math>
+We can see that now internal and external states are entangled.
+If we include spontaneous emission at rate <math>\Gamma</math>, the energy level of the excited state essentially broadens. Then, there are more levels to which we can couple, such as <math>|e,\pm 2 \hbar k \rangle </math>, which in turn can couple to <math>|g, \pm 3 \hbar k \rangle</math>. These transitions have different resonant frequencies, shifted by <math>\Delta E \propto E_r=\frac{\hbar^2 k^2}{2 m}</math>. If the width of the excited state <math>\Gamma \gg E_r/\hbar</math>, these transitions contribute and the dark state disappears (or at least decreases in "darkness"). However, a small <math>\Gamma</math> just broadens the width of the k-space distributions in the dark state.
+Such a dark state has been observed in VSCPT experiments: the momentum distribution consists of two peaks centered at <math>\pm \hbar k</math>. See, for example, the first observation of [http://journals.aps.org/prl/pdf/10.1103/PhysRevLett.61.826 Cooling below the single photon recoil limit by vscpt (Phys. Rev. Lett. 61, 826 (1988))]
+[[Image:VSCPT.png|center|500px]] [http://journals.aps.org/rmp/pdf/10.1103/RevModPhys.70.707 Manipulating atoms with photons, Cohen-Tannoudji (Rev. Mod. Phys. 70, 707)]
+Atoms in time of flight after the application of Raman beams. They split into two groups with momenta <math>\hbar k</math> and <math>-\hbar k</math> respectively.
+=== STIRAP ===
-On the other hand, for continuous excitation (not a short pulse), saturation of the atom leads to emission of increasingly incoherent light (Mollow triplet). For Mollow triplet, see Cohen-Tannoudji p:424.
+What happens if you change <math> \Omega_1 </math> and <math> \Omega_2 </math> slowly, i.e. adiabatically?  Stimulated Raman adiabatic passage, STIRAP, is an application for this situation.
-Next, consider a coherent light which is very weak. Monochromatic, coherent light is represented by a coherent state<math>|\alpha ></math> that has a Poissonian distribution of photon numbers: <math>|\alpha >=e^{-\frac{1}{2}|\alpha|^{2}}  \sum_{n = 0}^{\infty } \frac{ \alpha^{n}}{\sqrt{n+1}} |n></math>. For <math>|\alpha | \ll 1 </math>, the population of the states with <math>n > 1</math> is negligible, and the atom prepared in a state <math>|g>+\epsilon |e></math> with <math>|\epsilon | \ll 1</math> emits a coherent state of light, in agreement with what is expected for small saturation.
+For simplicity, let's assume that <math> \delta=0 </math> and lasers are blue detuned.  You first turn up the laser 2 and then turn up the laser 1, turning down the laser 2.  In the end, you turn down the laser 1.  In this condition, the dark state is initially <math>| g1 \rangle </math>, as <math>\Omega_2 \neq 0 </math>.  Then the dark state gradually becomes <math>| g2 \rangle </math>.  Thus, you can coherently move the population from <math>| g1 \rangle </math> to <math>| g2 \rangle </math>.  Here, the dark state is the lowest energy state, because it has no AC Stark shift, whereas the energy level of the bright state goes up due to the blue detuned light.  The pulse sequence is counter-intuitive.  In order to talk to the atoms in <math>| g1 \rangle </math>, you first turn up the laser that connects <math>| e \rangle </math> and <math>| g2 \rangle </math>.
-== First observation of coherent population trapping CPT ==
+[[Image:STIRAP1.png|center|200px]]
+[[Image:STIRAPScheme.png|center|400px]]
-Prepare a multimode laser with regular frequency spacing (<math>v_1, \cdots</math>, in the figure).
+When you have the red detuned light and when <math>| g1 \rangle </math> and <math>| g2 \rangle </math> are not degenerate, you get the same result.  In these cases, <math>| g1,N_1, N_2 \rangle </math> and <math>| g2, N_1-1, N_2-1 \rangle </math> are generate, where <math>N_1 </math> and <math>N_1 </math> are the photon number for the laser 1 and 2.
-[[Image:Fig_CPT_convert_20100416042234.jpg]]
+[[Image:STIRAP2.png|center|200px]]
+[[Image:STIRAP3.png|center|200px]]
-Prepare a gas in a cylindrical volume with gradient of magnetic field in z direction, and observe fluorescence.
+STIRAP is a dark state transfer.  How can we go from <math>| g1 \rangle </math> to <math>| g2 \rangle </math> without building up population in <math>| e \rangle </math>?  The answer is, there is a slight population in <math>| e \rangle </math>.  Let's check this with Schrödinger equation.
-Dark regions show the phaces where Zeeman shift between magnetic sublevels equals frequency difference between laser modes.
+:<math>\begin{align}
+i\left(
+\begin{array}{c}
+\dot{c}_{g1}  \\
+\dot{c}_e  \\
+\dot{c}_{g2}
+\end{array}
+\right) =
+\left(
+\begin{array}{ccc}
+& \Omega_1/2 & 0 \\
+\Omega_1/2 & 0 & \Omega_2/2  \\
+& \Omega_2/2 & 0
+\end{array}
+\right)
+\left(
+\begin{array}{ccc}
+c_{g1} \\
+c_e \\
+c_{g2}
+\end{array}
+\right)
+\end{align}
+</math>
+:<math>
+\dot{c}_{g2} = i\frac{\Omega_2}{2}c_e
+ </math>
+As we want <math>|c_{g2}|=1 </math> after the time for the transfer,
+:<math>
+c_e \approx  \frac{1}{\Omega_2 t_{{\rm transfer}}}
+</math>
+:<math>
+p_e \sim  \frac{1}{\Omega_2^2t_{{\rm transfer}}^2}
+ </math>
+The probability for the spontaneous emission is
+:<math>
+\Gamma \rho_e \approx \frac{\Gamma}{\Omega_2^2t_{{\rm transfer}}^2} \rightarrow 0
+ </math>
+as <math>\Omega_2\rightarrow \infty  </math> or <math>t_{{\rm transfer}}\rightarrow \infty  </math>. However, <math>t_{{\rm transfer}} </math> has to be smaller than coherent time of the <math>| g1 \rangle </math> and <math>| g2 \rangle </math> states.  The point here is that the rate of the state transfer is proportional to the amplitude of the excited state.  In this sense, the transfer is more efficient than optical pumping, whose rate of the transfer is proportional to the population of the excited state.  Since the spontaneous emission from the excited state is proportional to the population, this incoherent process is suppressed in STIRAP by the factor of <math> \frac{1}{\Omega_2 t_{{\rm transfer}}} </math>.  When you compare STIRAP with two photon Rabi flipping, that is, two photon <math> \pi </math> pulse, the efficiency is the same.  The reason STIRAP is better is that STIRAP has some robustness that two photon <math> \pi </math> pulse does not have.  It does not get as much effect by the frequency instability as Rabi scheme, and you don't have to worry about the exact length of the pulse in STIRAP.
-== Absorption calculation by interference, gain without inversion ==
+=== Gain without Inversion ===
-(Steve Harris, PRL 62, 1033 (1989))
+When you have a laser, common belief is that you need to have more atoms in excited state than ground state.  However, this is not necessarily the same for the three level system B system with two unstable states that decay by coupling to the same continuum (i.e. same polarization).  Suppose you send the population from the ground state by shining a laser of a frequency between two excited state energy.  The matrix element for the transition by the second order perturbation theory is
-http://prl.aps.org/abstract/PRL/v62/i9/p1033_1
+:<math>
+{\cal M}=\sum_{j=1,2}\frac{\langle {\rm cont}| V | e_j \rangle \langle e_j | V | g \rangle}{\Delta_j - i\Gamma_j/2}
+ </math>
-It is commonly believed that we need <math>N_e > N_ g</math> for optical gain. But: Consider a V system with two unstable states that decay by coupling to the same continuum (This is a fairly special situation, e.g. different m-levels do not qualify, since they emit photons of different polarizations, thus the continue <math>|k_1></math> or <math>|k_2></math> are distinguishable.)
+[[Image:GainWithoutInversion.png|center|250px]]
-[[Image:Fig_darkresonance_convert_20100416034152.jpg]]
+There is an <math>\omega_0 </math> for which the two terms almost cancel, when <math>|\Delta_1|,\ |\Delta_2|\gg \Gamma_1,\ \Gamma_2 </math>.  When you have atoms in the ground state and the laser frequency is <math>\omega_0 </math>, you will see a quantum interference due to the multiple paths to the continuum.  When you have a population in <math>|e_2 \rangle </math> state that is much smaller than that in the ground state and you shine the <math>\omega_0 </math> laser, you see the light due to the laser itself plus the induced emission of <math>\omega_0 </math> from <math>|e_2 \rangle </math>.  There is a gain in this frequency though there is no population inversion.  In other words, there is destructive interference between <math>|e_1 \rangle </math> and <math>|e_2 \rangle </math> for the absorption from the ground state, but not for the gain.
-Consider three level systems as in the figure where <math>|e_1></math> and <math>|e_2></math> decay to the continuum. A surprising feature of this system is the fact that there is a frequency at which the absorption rate becomes zero. To formally confirm this, we need to compute the second-order matrix element <math>M = \sum_{i =1 ,2} \frac{<continuum| V | e_i ><e_i | V |g> }{ \Delta_i - i \frac{\Gamma_i}{2}}</math>. Then, we know that there is a frequency at which this matrix element almost cancels.  Let the frequency be <math>\omega _ o</math> that corresponds to an energy between the two levels. Note <math>\omega _ o</math> depends on the two matrix elements and we assume <math>(|\Delta_1| , |\Delta_2| \gg r_1, r_2</math>.
+[[Image:GainWithoutInversion2.png|center|150px]]
-One may understand this by considering the fact that the two-photon scattering process <math>|g>\rightarrow |continuum></math> can proceed via two pathways that are fundamentally indistinguishable. In other words, it is impossible to tell whether it came from <math>|e_1></math> or <math>|e_2></math>. Thus, we need to consider quantum interference between them.
+There are some possible realization for this system.  One is hydrogen and DC electric field.  The mixing of 2S state and 2P state by the DC electric field gives two wide field.  Another is to use AC electric field to mix the S state and P state.  If you have <math>\Lambda </math> system with two degenerate ground state, you can make a gain without inversion by distributing the population as follows: none in <math>|g \rangle </math>, a little in <math>|e \rangle </math> and most in <math>|f \rangle </math>, whose population is hidden.
-Now assume that with some mechanism we populate, say, <math>|e_2></math> with a small number of atoms <math>N_2<N_ g</math>. These atoms have maximum stimulated emission probability on resonance, <math>|e_2>\rightarrow |g></math>, but there is also even larger absorption, since <math>N_ g>N_2</math>. However, because of the finite linewidth <math>r_2</math> of level <math>|e_2></math>, there is also stimulated emission gain at the "magical" (absorption-free) frequency <math>\omega _ o</math>. Since the <math>N_ g</math> atoms do not absorb here, there is net gain at this frequency in spite of <math>N_2<N_ g</math>, which can lead to "lasing without inversion." Note: this only works if the two excited states decay to the same continuum, such that the paths are indistinguishable. How can a system for lasing without inversion be realized?
+[[Image:GainWithoutInversion3.png|center|250px]]
+[[Image:GainWithoutInversion4.png|center|250px]]
-Possibility 1: hydrogen and dc electric field
-[[Image:Fig_examplessssss_convert_20100416034611.jpg‎]]
+For more detailed discussion, refer to Phys. Rev. Lett. 62, 1033.
-Possibility 2: use ac electric field to mix non-degenerate s state with p state.
+http://prl.aps.org/abstract/PRL/v62/i9/p1033\_1
 == Electromagnetically induced transparency ==
+===EIT in the dressed state picture===
 "Is it possible to send a laser beam through a brick wall?"
 Radio Yerevan: "In principle yes, but you need another very powerful laser..."
+The light interaction Hamiltonian in the dipole approximation is <math>H_{\text{int}}=-\mathbf{d} \cdot \mathbf{E}</math>, where the dipole operator <math>\mathbf{d}=\mathbf{d_1}+\mathbf{d_2}</math> is comprised of individual dipole moments <math>\mathbf{d_1}</math> and <math>\mathbf{d_2}</math> corresponding to the transitions <math>|g_1\rangle \leftrightarrow |e\rangle</math> and <math>|g_2\rangle \leftrightarrow |e\rangle</math>, respectively. In expanding out the interaction Hamiltonian we drop the cross terms <math>\mathbf{d_2} \cdot \mathbf{E_1}</math>, thus assuming that <math>\mathbf{E_1}</math> does not couple <math>g_2\rangle \leftrightarrow |e\rangle</math> and visa versa (this assumption is justified if the ground state splitting is much larger than the detuning of the light fields).  The interaction Hamiltonian then becomes
+:<math>
+H_{\text{int}}=-\mathbf{d_1}\cdot \mathbf{E_1}\cos(\omega_{L,1}) -\mathbf{d_2}\cdot \mathbf{E_2}\cos(\omega_{L,2}) = \hbar \Omega_1|e\rangle\langle g_1| \cos(\omega_{L,1}t) + \hbar \Omega_2 |e\rangle\langle g_2|\cos(\omega_{L,2}t) + h.c.
+</math>
+where we have introduced the Rabi frequencies, <math>\Omega_i=-\langle g_i | \mathbf{d_i} \cdot \mathbf{E_i} |e\rangle/\hbar</math>.
+As usual in semi-classical light matter interaction problems, we switch to the rotating frame of the light field defined by
+:<math>| \tilde {\Psi} \rangle = c_1(t) e^{-i\omega_{L,1}t} |g_1\rangle + c_2(t) e^{-i\omega_{L,2}t} |g_2\rangle + c_3(t)|e\rangle</math>.
+The total Hamiltonian in this new basis is thus
+:<math>
+\tilde{H}_0+\tilde{H}_\text{int}=\dfrac{\hbar}{2}
+\left(\begin{array}{ccc}
+& \Omega_1 & \Omega_2 \\
+		\Omega_1 & 2\Delta_1 & 0 \\
+		\Omega_2 & 0 & 2\Delta_2
+	\end{array}\right)
+</math>
 Steve Harris thought initially of special, ionizing excited states. However it is possible to realize the requirement of identical decay paths in a <math>\lambda</math>-system with a a(strong) coupling laser. The phenomenon is closely related to coherent population trapping.
@@ Line 246: / Line 493: @@
 As we turn up the power of the coupling laser the transmission improves and then broadens (in the realistic case of a finite decoherence rate <math>\gamma_{gf}=0</math>, an infinitesimally small coupling Rabi frequency, but the frequency window over which transmission occurs is very narrow and given by <math>\Delta \omega =\Omega_c</math>.
+===EIT vs CPT. What's the difference?===
+Sometimes in the literature CPT and EIT are treated as two different phenomena, while here we have treated the two with a similar formulation. Are they different? The short answer is no. The long answer is that CPT is a "trapping" effect, and relies on spontaneous emission to produce the coherent dark state (i.e., spontaneous emission allows for the system to undergo a random walk in phase space until it falls into a "trapped" state, no longer coupled to spontaneous emission). For example, in VSCPT, very low temperatures are attained because the the atoms undergo many spontaneous emission events and are pumped into the dark state. On the other hand EIT experiments are usually prepared adiabatically: A strong pump beam initializes the atomic state, and then the weak probe beam adiabatically prepares the dark state, with no spontaneous emission. Another contrast is that CPT experiments focus on trapping of atoms, while EIT experiments are more concerned with the effect of the atoms on cross-modulating the two light beams. However, the underlying physics for both effects is the same.
+===Further theoretical treatment===
+The approach to EIT presented here has relied greatly on intuition. For the interested reader, there are two very interesting approaches not covered here. The first is using the optical Bloch equations (which are outside the scope of 8.421) to treat the effect of spontaneous emission explicitly, and thus calculate the widths of the EIT resonance feature. A good resource for this is the section "Master equation and linear susceptibility" in Rev. Mod. Phys. 77, 633 (2005). http://journals.aps.org/rmp/abstract/10.1103/RevModPhys.77.633
+Another approach is to ask the question: Is EIT a quantum effect? In many ways it is not, and it can be modeled by a coupled system of two mass-spring harmonic oscillators, which is studied in careful detail here: http://arxiv.org/abs/quant-ph/0107061 .
 == EIT: Eigenstates picture ==
-Using the field quantization to easily include energy conservation, we see that the states are coupled in triplets:
+Using the field quantization to easily include energy conservation, we see that the states are coupled in triplets.
+[[File:classCoherence1b.png|400px]]
+We can go into the dressed atom picture and use the uncoupled states as our basis states.
+(Note: in the dressed-atom picture, the levels are denoted by <math>|\mathrm{atom} \rangle |\mathrm{photon}\rangle</math>. The atom, in this case, is in one of the three states <math>|g\rangle,|e\rangle,|f\rangle</math> and the photon is in a Fock state (a state with fixed photon number) with photon numbers <math>n</math> and <math>m</math>.
-[[Image:L24tmpfig1.JPG]]
+[[File:classCoherence1c.png|600px]]
-So the Hamiltonian is given by <math>\stackrel{\frac{\omega _1}{2}=g_ 1\sqrt {n}}{\frac{\omega _2}{2}=g_ 2\sqrt {m}}</math>
+<!-- [[Image:L24tmpfig1.JPG]] -->
+The Rabi frequencies for the two transitions are <math> g_1 \sqrt{n} , g_2 \sqrt{m}</math> and the Hamiltonian written in the basis <math>\left( |g,n,m-1\rangle, |e,n-1,m-1\rangle, |f,n-1,m\rangle \right)</math>is:
 :<math>\begin{align}  H = \hbar \left( \begin{array}{ccc} 0 &  g_1\sqrt {n} &  0 \\ g_1\sqrt {n} &  \Delta &  g_2\sqrt {m} \\ 0 &  g_2\sqrt {m} &  -\delta \end{array} \right) \end{align}</math>
@@ Line 258: / Line 522: @@
 On resonance <math>\Delta =\delta =0</math> the Eigenstates are
-[[Image:L24tmpfig2.JPG]]
-:<math>C_1''|g>+C_2''|e>+C_3''|f>=|BI></math><br>   <math>C,|g>+C_3|f>=|D></math><br>   <math>C_1'|g>+C_2'|e>+C_3'|f>=|BII></math>
+[[File:classCoherence2.png|400px]]
+<!-- [[Image:L24tmpfig2.JPG]] -->
-In the limit of weak probe and a strong pump,
+:<math>|B1\rangle = g_1\sqrt{n} \; |g,n,m-1\rangle +\sqrt{n g_1^2 + m g_2^2} \; |e,n-1,m-1\rangle + g_2 \sqrt{m} \; |f,n-1,m\rangle </math>
+:<math>|D\rangle = g_2\sqrt{m} \; |g,n,m-1\rangle + g_1 \sqrt{n} \; |f,n-1,m\rangle </math>
+:<math>|B2\rangle = g_1\sqrt{n} \; |g,n,m-1\rangle -\sqrt{n g_1^2 + m g_2^2} \; |e,n-1,m-1\rangle + g_2 \sqrt{m} \; |f,n-1,m\rangle </math>
+Note: these are unnormalized.
-[[Image:L24tmpfig3.JPG]]
+To understand the role of path interference in the formation of EIT, let's consider the limit of weak probe and a strong pump: <math>n \ll m</math>. We can limit the analysis to <math>n=1</math>. Then we can diagonalize the strong coupling, and treat the probe perturbatively. From the diagonalization above, we can see that in this limit the dark state is mostly the <math>|g,1,m\rangle</math> state and the bright states are strong superpositions of <math>|e,0,m\rangle, |f,0,m+1\rangle</math>.
-we can limit the analysis to <math>n=0,1,m\gg 1</math>. Then we can diagonalize the strong coupling, and treat the probe perturbatively
+<!--[[Image:L24tmpfig3.JPG]] -->
+<!-- [[Image:L24tmpfig4.JPG]] -->
-[[Image:L24tmpfig4.JPG]]
+We want to know if the probe beam is absorbed and with what probability. We consider the problem in which we start with one photon in the probe beam and 0 photons in all other modes except in the pump mode (which we omit in the notation for simplicity), i.e. in <math>|g,0\rangle |0,\cdots 0,\cdots \rangle</math>. That is, we want the final state to be <math>|g,0\rangle|0,\cdots 1,0,\cdots \rangle</math>. Absorption of this photon has to be accompanied by emission, making this a two-photon scattering problem. There are two paths the photon can take: either via <math>|B1'\rangle</math> or via <math>|B2'\rangle</math>. The matrix element contains two intermediate states with opposite detunings. Calling the perturbing Hamiltonian V for simplicity, we get that the transition amplitude is:
-Again we have a scattering problem <math>|g,|>\otimes |0...0>\rightarrow |g,0>\otimes |...0|_{\kappa _1}0...></math>
+<math>M=\frac{\langle g,0|\langle 0,\cdots 1,0\cdots |V'|B1'\rangle\langle B1'|V|g,1\rangle |0,\cdots 0,\cdots \rangle }{-\Delta'/2}+\frac{\langle g,0|\langle 0,\cdots 1,0\cdots |V|B2'\rangle\langle B2'|V|g,1\rangle |0,\cdots 0,\cdots \rangle}{\Delta'/2}</math>
-via a two photon process. The matrix element contains two intermediate states with opposite detunings.
-<math>M=\frac{<g,0|V'|BI><BI|V|g,|>}{-\frac{\Delta }{2}}+\frac{<g,0'|V'|BII><BII|V|g,|>}{\frac{\Delta }{2}}</math>
+[[File:classCoherence3a.png|500px]]
-On one- and two-photon resonance all couplings are symmetric in <math>|BI></math> and <math>|B2></math>, the detunings are opposite, and the matrix element M vanishes: electromagnetically induced transparency (EIT). If the pump remains on resonance and we tune the probe field, then the couplings are still symmetric in <math>|BI></math>, <math>|B2></math>, but the detunings are <math>\frac{(\Delta \pm \delta )}{2}</math>, and the matrix element does not vanish. Maximum scattering is obtained when we tune to one of the bright states
-[[Image:L24tmpfig5.JPG]]
+On one- and two-photon resonance all couplings are symmetric in <math>|B1'></math> and <math>|B2'></math>, the detunings are opposite, and the matrix element M vanishes: electromagnetically induced transparency (EIT) - the photon in not absorbed. If the pump remains on resonance and we tune the probe field, then the couplings are still symmetric in <math>|B1'\rangle</math>, <math>|B2'\rangle</math>, but the detunings are <math>\frac{\bar{\Delta'}}{2} \pm \delta </math>, and the matrix element does not vanish. Maximum scattering is obtained when we tune to one of the bright states.
-[[Image:L24tmpfig6.JPG]]
+[[File:Slide2.jpg|500px|]]
-When we include the decay <math>|e>\rightarrow |g>,|f></math> within the system, we can no longer use the Hamiltonian formalism, but must use density matrices. Nevertheless, the eigenstates provide physical insight into the problem.
+The figure shows the absorption of the probe beam. The frequency of the probe beam is <math>\omega_p</math> and the frequency difference between the bring and the dark state is <math>\omega_{BD}</math>. In the case of strong pump, this is the Rabi frequency <math>\Delta'/2</math> above). (a) <math>\Delta' \leq \Gamma</math>; (b)<math>\Delta' \gg \Gamma</math>. Figure adapted from  [[ Rev.Mod.Phys. 77, 633]]
+<!-- [[Image:L24tmpfig5.JPG]] -->
+<!-- [[Image:L24tmpfig6.JPG]] -->
+When we include the decay <math>|e\rangle\rightarrow |g\rangle,|f\rangle</math> within the system, we can no longer use the Hamiltonian formalism, but must use density matrices. Nevertheless, the eigenstates provide physical insight into the problem.
 <br style="clear: both" />
@@ Line 305: / Line 578: @@
 [[Image:L24tmpfig10.JPG]]
-Procedure: turn on <math>\omega _ B</math> first coupling empty level, ramp up <math>\omega_A</math>, ramp down <math>|\omega_ B\rightarrow </math> adiabatic transfer <math>|g_ A>|\delta >_ B|0>_ c\rightarrow |\delta >_ A|g>_ B|0>_ c</math> via dark state of the cavity. Note that the probability to find the photon in the cavity can be made very small while maintaining full transfer: virtual states.
+Procedure: turn on <math>\omega _ B</math> first coupling empty level, ramp up <math>\omega_A</math>, ramp down <math>|\omega_ B\rightarrow </math> adiabatic transfer <math>|g_ A\rangle|\delta \rangle_ B|0\rangle_ c\rightarrow |\delta \rangle_ A|g\rangle_ B|0\rangle_ c</math> via dark state of the cavity. Note that the probability to find the photon in the cavity can be made very small while maintaining full transfer: virtual states.
 [[Image:L24tmpfig11.JPG]]
@@ Line 313: / Line 586: @@
 Verification and entanglement:
-<math>\frac{1}{\sqrt {2}}(|g>|f>+e^{i\phi }|f>|g>)</math> well-defined phase must exist
+<math>\frac{1}{\sqrt {2}}(|g\rangle|f\rangle+e^{i\phi }|f\rangle|g\rangle)</math> well-defined phase must exist
 How to verify? Simultaneous readout, super and sub radiant states
@@ Line 330: / Line 603: @@
 <br style="clear: both" />
 == On the "magic" of dark-state adiabatic transfer ==
-[[Image:L24tmpfig14.JPG]]
+[[File:STIRAP.png|500px]]
+<!--  [[Image:L24tmpfig14.JPG]] -->
+How is it that we can transfer the population completely form state |g&gt; to state |f&gt; through the state |e&gt; while keeping the unstable state |e&gt; unpopulated? (The correct statement is "...while keeping the population of |e&gt; negligibly small"). This is possible through coherence-interference: on resonance the eqs of motion for the amplitudes of the three states read
-How is it that we can transfer the population completely form state |g&gt; to state |f&gt; through the state |e&gt; while keeping the unstable state |e&gt; unpopulated? (The correct statement is "...while keeping the population of |e&gt; negligibly small"). This is possible through coherence-interference: n resonance the eqs of motion for the amplitude read
 :<math>\begin{align}  i\left( \begin{array}{c} C_ g \\ C_ e \\ C_ f \end{array} \right) = \left( \begin{array}{ccc} 0 &  \frac{\omega _1}{2} &  0 \\ \frac{\omega _1}{2} &  0 &  \frac{\omega _2}{2} \\ 0 &  \frac{\omega _2}{2} &  0 \end{array} \right) \left( \begin{array}{c} C_ g \\ C_ e \\ C_ f \end{array} \right) \end{align}</math>
@@ Line 340: / Line 617: @@
 <math>\dot{C}_ g=-i\frac{\omega _1}{2}C_ e</math> <math>\dot{C}_ e=-i\frac{\omega _1}{2}C_ g -i\frac{\omega _2}{2}C_ f</math> <math>\dot{C}_ f=-i\frac{\omega _2}{2}C_ e</math>
-[[Image:L24tmpfig15.JPG]]
+<!-- [[Image:L24tmpfig15.JPG]] -->
+Let's assume initially <math>C_g(t=0)=1, C_e(t=0)=0, C_f(t=0)=0</math>.
 For adiabatic transfer we have <math>\omega _2\gg \omega _1</math> and amplitude flow as
-[[Image:L24tmpfig16.JPG]]
+[[File:STIRAPa.png|400px]]
-So we see how |f&gt; accumulates amplitude because it arrives there always with the same phase factor -1, whereas the flow back from |f&gt; into |e&gt; leads to a destructive interference in |e&gt; with the amplitude flow from |g&gt;, keeping the amplitude in |e&gt; small at all times, while the amplitude on |f&gt; keeps growing. If the state |f&gt; were to acquire a random phase <underline>
+<!-- [[Image:L24tmpfig16.JPG]] -->
-<attributes>
-</attributes>
+So we see how <math>|f\rangle</math> accumulates amplitude because it arrives there always with the same phase factor -1, whereas the flow back from <math>|f\rangle</math> into <math>|e\rangle</math> leads to a destructive interference in <math>|e\rangle</math> with the amplitude flow from <math>|g\rangle</math>, keeping the amplitude in <math>|e\rangle</math> small at all times, while the amplitude on <math>|f\rangle</math> keeps growing. If the state <math>|f\rangle</math> were to acquire a random phase relative to <math>|g\rangle</math> due to some other interaction, then the constructive interference leading to the accumulation of amplitude in <math>|f\rangle</math> and the destructive interference in <math>|e\rangle</math> would not work. The dark state transfer requires g-f coherence.
-relative to |g&gt;
-</underline> due to some other interaction, then the constructive interference leading to the accumulation of amplitude in |f&gt; and the destructive interference in |e&gt; would not work. The dark state transfer requires g-f coherence.
-== Two-phase absorption, Fano profiles ==
+== Two-photon absorption features. Fano profiles ==
+We start with a 3-level system we have seen before but now we assume large one-photon detuning, <math>\Delta_1,\Delta_2 \gg \Gamma</math>, weak probe (Rabi frequency <math>\Omega _1</math>) and strong pump field (Rabi frequency <math>\Omega _2</math>) and let's define the two-photon detuning <math>\delta =\Delta _1-\Delta _2</math>.
-Let us assume large one-photon detuning, <math>\Delta \gg \Gamma</math>, weak probe <math>\omega _1</math> and strong control field <math>\omega _2</math> (we also define the two-photon detuning <math>\delta =\Delta _1-\Delta _2</math>).
+[[File:Fano1a.png|500px]]
-[[Image:EIT_levels.jpg||400px]]
+<!-- [[Image:EIT_levels.jpg||400px]] -->
-In this limit analytic expressions for the absorption cross section for beam <math>\omega _1</math> and the refractive index seen by beam <math>\omega _1</math> exist, e.g. [[http://pra.aps.org/abstract/PRA/v56/i3/p2385_1 Muller et al., PRA 56, 2385 (1997)]]
+In this limit analytic expressions for the absorption cross section for beam <math>\Omega _1</math> and the refractive index seen by beam <math>\Omega _1</math> exist, e.g. [[http://pra.aps.org/abstract/PRA/v56/i3/p2385_1 Muller et al., PRA 56, 2385 (1997)]]
-The refractive index is given by: <math>n(d)=1+\frac{3}{8\pi }\tilde{n}\lambda ^3f(\Delta )</math>
+The refractive index is given by: <math>n(\delta)=1+\frac{3}{8\pi^2 }\tilde{n}\lambda ^3f(\delta )</math>
-where <math>\tilde{n}</math> is the atomic density, <math>f(\delta )=\frac{\Gamma}{2}\delta \frac{A}{A^2+B^2},A=\omega _2^2-\delta \Delta _2, B=\delta\Gamma</math>.
+where <math>\tilde{n}</math> is the atomic density, <math>f(\delta )=\frac{\Gamma}{2}\delta \frac{A}{A^2+B^2},A=\Omega _2^2-\delta \Delta _2, B=\delta\Gamma</math>.
-For zero ground-state linewidth (decoherence between the ground-states) <math> \sigma(\delta)=\sigma_{0}.g\left(\delta\right)</math> where <math>\sigma_0=\frac{3}{2\pi}\lambda^2</math> is the resonant cross-section, and <math>g(\Delta)=\frac{\Gamma}{2}\frac{\delta B}{A^2+B^2}</math>.
+For zero ground-state linewidth (decoherence between the ground-states) <math> \sigma(\delta)=\sigma_{0}.g\left(\delta\right)</math> where <math>\sigma_0=\frac{3}{2\pi}\lambda^2</math> is the resonant cross-section, and <math>g(\delta)=\frac{\Gamma}{2}\frac{\delta B}{A^2+B^2}</math>.
-The absorption cross section for <math>\Delta _2>0</math>:
+There are several features of the absorption of the probe beam <math>\Omega_1</math>
-[[Image:Fano_profile.jpg||800px]]
+) Raman Resonance: <math>\delta=0</math>
-This is like a ground state coupling to one narrow and one wide excited state, except that there is EIT in between because both states decay to the same continuum.
+This is the situation we have discussed before: EIT
-[[Image:New_states.jpg|center||300px]]
+) No pump: <math>\Omega_2=0</math>
-At <math>\delta=\Delta _{2}</math> , we have one-photon absorption, which is a two-photon scattering process:
+This is the situation of a two-level system. When the probe beam is on resonance <math>\Delta_1=0 \rightarrow \delta=\Delta_2</math>  (here there is no pump beam, so <math>\Delta_2=0</math>), then the pump is completely absorbed and we have the single-photon absorption feature of width <math>\Gamma</math>, which is a two-photon scattering process:
 [[Image:One_photon_abs.jpg|center||150px]]
-At <math>\delta=-\frac{\omega _2^2}{\Delta _2}</math>, two-photon absorption, which is (at least) four-photon scattering process:
+) Strong pump
+Here, the <math>|e\rangle</math> and <math>|f\rangle</math> levels are strongly coupled and, consequently, AC-Stark shifted. Since <math>\Omega_1 </math> is assumed to be small, the <math>|g\rangle</math> state is effectively not altered by <math>\Omega_1</math> . With this assumption, the eigenstates of the Hamiltonian consist of one ground state (same as before, <math>|g\rangle</math>) and two excited states which are now superpositions of the original <math>|f\rangle</math> and <math>|e\rangle</math> states (the superposition can be determined to first order by assuming a two-level system of <math>|f\rangle</math> and <math>|e\rangle</math> coupled with Rabi frequency <math>\Omega_2</math> and detuning <math>\Delta_2</math>). The ground state is then coupled by the weak <math>\Omega_1</math> to a narrow and a broad state
+[[Image:New_states.jpg|center||300px]]
+Since both of these states are coupled to the same continuum, there can be interference between the possible absorption-emission paths starting from the ground state and we can get an EIT feature on Raman resonance, as discussed in 1).
+At <math>\delta=-\frac{\Omega _2^2}{\Delta _2}</math>, we have a two-photon absorption, which is (at least) four-photon scattering process:
 [[Image:Two_photon_abs.jpg|center||300px]]
+We can now plot the population in the excited state which gives us the absorption profile (see [http://cua.mit.edu/8.421/Papers/Lounis%20and%20Cohen-Tannoudj%20Fano%20profiles%20jp2v2p579.pdf Lounis and Cohen-Tannoudji on Fano profiles])
+[[File:EITFano2.jpg]]
+<!-- [[Image:Fano_profile.jpg||800px]] -->
 For the EIT condition <math>\delta =0</math>, there is no coupling to the excited state, and the refractive index is zero. In the vicinity of EIT, there is steep dispersion, resulting in a strong alteration of the group velocity of light<math>\rightarrow </math> slowing and stopping light.
-[[Image:Index_of_refraction.jpg||800px]]
+<!-- [[Image:Index_of_refraction.jpg||800px]] -->
 <br style="clear: both" />
 == Slow light, adiabatic changes of velocity of light ==
@@ Line 409: / Line 701: @@
 == Superradiance ==
-Assume that two identical atoms, one in its ground and the other in its excited state, are placed within a distance <math>d\gg \lambda _{eg}</math> of each other. What happens?
+Let's assume there are two identical atoms, one in its ground and the other in its excited state. They are placed within a distance <math>d\ll \lambda _{eg}</math> of each other. What happens?
-For a single atom we have, for the emission rate <math> R\left(t\right) </math> at time t is <math> R\left(t\right)=\Gamma e^{-\Gamma t}</math> (product of the spontaneous emission rate and occupation probability). Thus, the emission probability to have emitted a photon by time t is
-{{EqL
-|math=<math>p_{1}(t)=\int _0^ t R(t') dt'=1-e^{-\Gamma t}</math>
-|num=eqtn:superradiance1
-}}
+For a single atom, the emission rate <math> R\left(t\right) </math> at time t is <math> R\left(t\right)=\Gamma e^{-\Gamma t}</math> (product of the spontaneous emission rate and occupation probability). Thus, the emission probability to have emitted a photon by time t is
+:<math>p_{1}(t)=\int _0^ t R(t') dt'=1-e^{-\Gamma t}</math>
-[[Image:Single_atoms_decay.jpg|frame|center||300px]]
+[[Image:Single_atoms_decay1.jpg|frame|center|]]
-What about two atoms? It turns out that the correct answer is
+What happens to the two atoms case if there is only one atom in the excited state? It turns out that the correct answer is
-{{EqL
+<math>R_2\left(t\right)=\Gamma e^{-2 \Gamma t}</math>
-|math=<math>R_2\left(t\right)=\Gamma e^{-2 \Gamma t}</math>
+<math>p_2(t)=\int ^ t_0 R_2(t')dt'=\frac{1}{2}(1-e^{-2\Gamma t})</math>
-|num=eqtn:superradiance2
-}}
+[[Image:Two_atoms_decay2.jpg|frame|center|]]
+[[Image:Two_atoms_decay3.jpg|frame|center|]]
-{{EqL
+The photon is emitted with the same initial rate, but has only probability <math>\frac{1}{2}</math> of being emitted. It is saying there is still half probability for the atom remaining in the excited state. How can we understand this? The interaction Hamiltonian is:
-|math=<math>p_2(t)=\int ^ t_0 R_2(t')dt'=\frac{1}{2}(1-e^{-2rt})</math>
-|num=eqtn:superradiance3
-}}
+<math>V=-\vec{d}_1\cdot \vec{E}(\vec\gamma ,t)-\vec{d}_2\cdot \vec{E}(\vec\gamma ,t)=-\vec{D}\cdot \vec{E}(\vec\gamma ,t)</math>
-[[Image:Two_atoms_decay.jpg|frame|center||300px]]
-The photon is emitted with the same initial rate, but has only probability <math>\frac{1}{2}</math> of being emitted at all! How can we understand this? The interaction Hamiltonian is (classically):
-{{EqL
-|math=<math>V=-\vec{d}_1\cdot \vec{E}(\vec\gamma ,t)-\vec{d}_2\cdot \vec{E}(\vec\gamma ,t)=-\vec{D}\cdot \vec{E}(\vec\gamma ,t)</math>
-|num=eqtn:superradiance5
-}}
 In QED:
-{{EqL
+<math>V=\hbar g(\sigma ^+_1+\sigma ^-_1)(a+a^+)+\hbar g(\sigma _2^++\sigma _2^-)(a+a^+)</math> <math>=\hbar g(\sigma ^+_1+\sigma ^+_2+\sigma ^-_1+\sigma ^-_2)(a+a^+)=\hbar g(\Sigma ^++\Sigma ^-)(a+a^+)</math>
-|math=<math>V=\hbar g(\sigma ^+_1+\sigma ^-_1)(a+a^+)+\hbar g(\sigma _2^++\sigma _2^-)(a+a^+)</math> <math>=\hbar g(\sigma ^+_1+\sigma ^+_2+\sigma ^-_1+\sigma ^-_2)(a+a^+)=\hbar g(\Sigma ^++\Sigma ^-)(a+a^+)</math>
-|num=eqtn:superradiance6
-}}
 with <math>\Sigma ^{\pm }=\Sigma ^ 2_{i=1}\sigma ^{\pm }_ i, \vec{D}=\Sigma ^ 2_{i=1}\vec{d}_ i</math>
-Lecture XXVI
 <br style="clear: both" />
 == Superradiance, continued ==
 Now we can write the initial state as:
-<math>|ge,0>=\frac{1}{2}\underbrace{(|ge,0>+|eg,0>}_{\sqrt {2}|\mathrm{superradiant}>}+\underbrace{|ge,0>-|eg,0>)}_{\sqrt {2}|\mathrm{subradiant}>}</math>
+<math>|ge,0\rangle=\frac{1}{2}\underbrace{(|ge,0\rangle+|eg,0\rangle}_{\sqrt {2}|\mathrm{superradiant}\rangle}+\underbrace{|ge,0\rangle-|eg,0\rangle)}_{\sqrt {2}|\mathrm{subradiant}\rangle}</math>
 where
-<math>|\mathrm{superradiant}>=\frac{1}{\sqrt {2}}(|ge,0>+|eg,0>)</math>
+<math>|\mathrm{superradiant}\rangle=\frac{1}{\sqrt {2}}(|ge,0\rangle+|eg,0\rangle)</math>
-<math>|\mathrm{subradiant}>=\frac{1}{\sqrt {2}}(|ge,0>-|eg,0>)</math>
+<math>|\mathrm{subradiant}\rangle=\frac{1}{\sqrt {2}}(|ge,0\rangle-|eg,0\rangle)</math>
 and
-<math><gg,1|V|\mathrm{superradiant}>=\sqrt {2}\hbar g; <gg,1|V|\mathrm{subradiant}>=0</math>
+<math>\langle gg,1|V|\mathrm{superradiant}\rangle=\sqrt {2}\hbar g; \langle gg,1|V|\mathrm{subradiant}\rangle=0</math>
-The initial state has a 50% probability to be the sub-radiant state, hence the system has a 50% probability of not decaying. The set of four states <math>|gg,0>,|ge,0>,|eg,0>,|ee,0></math> can be organized into a triplet and a singlet:
+The initial state has a 50% probability to be the sub-radiant state, hence the system has a 50% probability of not decaying. The set of four states <math>|gg,0\rangle,|ge,0\rangle,|eg,0\rangle,|ee,0\rangle</math> can be organized into a triplet and a singlet:
 [[Image:twoAtomDicke.jpg]]
-The state <math>|ge>-|eg></math> is "dark" in that it does not decay under the action of the Hamiltonian V. The matrix elements between the states, indicated by arrows, are expressed in units of the single atom coupling <math>g=\frac{1}{\hbar }<e,0|V|g,1></math>.
+The state <math>|ge\rangle-|eg\rangle</math> is "dark" in that it does not decay under the action of the Hamiltonian V. The matrix elements between the states, indicated by arrows, are expressed in units of the single atom coupling <math>g=\frac{1}{\hbar }\langle e,0|V|g,1\rangle</math>.
-Just as we can identify the two-level system <math>|e>,|g></math>, with a (pseudo)spin <math>\frac{1}{2}</math>, we can identify the triplet and singlet states with <math>L=0,1</math>, and write
+Just as we can identify the two-level system <math>|e\rangle,|g\rangle</math>, with a (pseudo)spin <math>\frac{1}{2}</math>, we can identify the triplet and singlet states with <math>L=0,1</math>, and write
-<math>|L=1,M=1>=|ee></math>
+<math>|L=1,M=1\rangle=|ee\rangle</math>
-<math>|L=1,M=0>=(|eg>+|ge>)/\sqrt{2}</math>
+<math>|L=1,M=0\rangle=(|eg\rangle+|ge\rangle)/\sqrt{2}</math>
-<math>|L=1,M=-1>=|gg></math>
+<math>|L=1,M=-1\rangle=|gg\rangle</math>
-<math>|L=0,M=0>=(|ge>-|eg>)/\sqrt{2}</math>
+<math>|L=0,M=0\rangle=(|ge\rangle-|eg\rangle)/\sqrt{2}</math>
 Since V conserves parity (exchange of the two atoms), there is no coupling between singlet and triplet states. (This is no longer true when we consider spatially extended samples).
 == Supperradiance in N atoms ==
-It is not difficult to generalize the formalism to more atoms
-<math>V=-\vec{D}\cdot \vec{E}</math> with <math>\vec{D}=\Sigma^N_{i=1}\vec{d}_ i</math>
+First look at N spins in a magnetic field (NMR)
+[[Image:N_particel_SR1.jpg|center|frame|]]
+Dipole moment: <math>D=Nd</math>, power radiation <math>\propto D^2=N^2d^2</math>. There is N times more enhancement over N.
+For N excited atoms, we usually regard the atoms as independent. Therefore, power radiation scales as N.
+BUT: All two-level systems are equivalent. Which picture is correct?
+Answer: There is an important distinction between ''sample size <math>\gg \lambda</math>'' and ''sample size <math>\ll \lambda</math>''. For sample size <math>\gg \lambda</math>, which is usually the case for optical transitions, the particles can be treated independently. For sample size <math>\ll \lambda</math>, all particles interact with a common radiation field and thus cannot be treated independently.
+The coherence in spontaneous emission for N (localized) atoms requires two assumptions:
+. No interaction between atoms
+. Emitted photons (NOT the atoms) are indistinguishable. The particle symmetry (Bosons, Fermions) is irrelevant.
 The Dicke states, equivalent to the states obtained by summing N spin <math>\frac{1}{2}</math> particles, are
-[[Image:NAtomDicke.jpg]]
+[[Image:NAtomDicke.jpg|frame|center|]]
+Interaction with em field through <math>S_+</math>, <math>S_-</math>
+Matrix element responsible for spontaneous emission:
+<math>\langle S,M-1|S_-|S,M\rangle=\sqrt{(S-M+1)(S+M)}</math>
+Note matrix element only couple within one ladder. For single particle, <math>S=M=\frac{1}{2}\Rightarrow\langle S,M-1|S_-|S,M\rangle=1</math>.
+Rate (or intensity I) of radiation relative to a single particle:<math>I=(S-M+1)(S+M)</math>
+Let's look at <math>S=\frac{N}{2}</math>
+. [[Image:dicke ladder1.jpg]] Radiation rate I is the same as for N independent atoms
+. [[Image:dicke ladder2.jpg]] Radiation rate I <math>\propto N^2</math>, N times enhancement compared with N independent atoms <math>\rightarrow</math> characteristic for superradiant systems
+. [[Image:dicke ladder3.jpg]] <math>M=-\frac{N}{2}+1</math>. Only one particle is excited. BUT: I=N <math>\Rightarrow</math> N times enhancement.
+The matrix element can be calculated as <math>\frac{1}{\sqrt{N}}\underbrace{(|egg\cdots g\rangle+|geg\cdots g\rangle+\cdots +|ggg\cdots e\rangle}_{N terms})=\sqrt{N}g</math>. We can also get the matrix element by symmetry argument (should be the same as <math>S\rightarrow S-1</math>).
 Let us look at the leftmost (symmetric) ladder. Near the middle of the Dicke-ladder, <math>M\simeq 0</math>, the matrix element is
 <math>
-<V> \simeq \sqrt {\frac{N}{2}(\frac{N}{2}-1)}g\simeq N g.
+\langle V\rangle \simeq \sqrt {\frac{N}{2}(\frac{N}{2}+1)}g\simeq N g.
 </math>
-The emission rate is proportional to <math>|<V>|^2\simeq N^2g^2</math>, i.e. the rate is quadratic in atom number.
+The emission rate is proportional to <math>|\langle V\rangle|^2\simeq N^2g^2</math>, i.e. the rate is quadratic in atom number.
-Classically, that is not too surprising: we have N dipoles oscillating in phase, which corresponds to a dipole <math>D=Nd</math>, the emission is proportional to <math>D^2=N^2d^2</math>. However, the Dicke states have <math><D>=0</math> and nevertheless macroscopic emission. How do we see this? In the Bloch sphere, for the angular momentum representation the coherent state <math>|L=N/2,M=-N/2>=|g...g></math> corresponds to all atoms in the ground state.
+Classically, that is not too surprising: we have N dipoles oscillating in phase, which corresponds to a dipole <math>D=Nd</math>, the emission is proportional to <math>D^2=N^2d^2</math>. However, the Dicke states have <math>\langle D\rangle=0</math> and nevertheless macroscopic emission. How do we see this? In the Bloch sphere, for the angular momentum representation the coherent state <math>|L=N/2,M=-N/2\rangle=|g\cdots g\rangle</math> corresponds to all atoms in the ground state.
-A field that symmetrically couples to all atoms (e.g. <math>\frac{\pi }{2},\pi </math> pulse) acts only within the completely symmetric Hilbert space <math>L=N/2</math>. This space consists of  states like <math>(\cos \theta |e>+\sin \theta e^{i\phi }|g>)^ N</math>, corresponding to rotations of the state <math>|g...g></math> around some axis on the Bloch sphere.
+A field that symmetrically couples to all atoms (e.g. <math>\frac{\pi }{2},\pi </math> pulse) acts only within the completely symmetric Hilbert space <math>L=N/2</math>. This space consists of  states like <math>(\cos \theta |e\rangle+\sin \theta e^{i\phi }|g\rangle)^ N</math>, corresponding to rotations of the state <math>|g\cdots g\rangle</math> around some axis on the Bloch sphere.
-The states obtained by rotations of the state <math>|g...g></math> by symmetric operations that act on all individual atoms independently, i.e. of the form <math>|g>\rightarrow \cos \theta |e>+e^{i\phi }\sin \theta |g></math>, are called coherent spin states (CSS). They are represented by a vector on the Bloch sphere with uncertainties <math>\sqrt {\frac{L}{2}}</math> in directions perpendicular to the Bloch vector.
+The states obtained by rotations of the state <math>|g\cdots g\rangle</math> by symmetric operations that act on all individual atoms independently, i.e. of the form <math>|g\rangle\rightarrow \cos \theta |e\rangle+e^{i\phi }\sin \theta |g\rangle</math>, are called coherent spin states (CSS). They are represented by a vector on the Bloch sphere with uncertainties <math>\sqrt {\frac{L}{2}}</math> in directions perpendicular to the Bloch vector.
-[[Image:BlochSphereCSS2.jpg|center]]
+[[Image:BlochSphereCSS2.jpg|center|frame|]]
-If we prepare a system in the CSS corresponding to a slight angle away form <math>\theta =0</math> near <math>|e...e>=|L=N/2,M=N/2></math>, then classically it will obey the eqs of motion of an inverted pendulum, and fall down along the Bloch sphere. (This can be shown using the classical analogy with a field.)
+If we prepare a system in the CSS corresponding to a slight angle away form <math>\theta =0</math> near <math>|e\cdots e\rangle=|L=N/2,M=N/2\rangle</math>, then classically it will obey the eqs of motion of an inverted pendulum, and fall down along the Bloch sphere. (This can be shown using the classical analogy with a field.)
-So what happens if we prepare the state <math>|M=+L>=|e...e></math>? Does it:
+Question1: So what happens if we prepare the state <math>|M=+L\rangle=|e\cdots e\rangle</math>? Does it:
-a. evolve down along the Dicke ladder maintaining <math><D>=0</math> (but <math><D^2>\neq 0</math>)?
+a. evolve down along the Dicke ladder maintaining <math>\langle D\rangle=0</math> (but <math>\langle D^2\rangle\neq 0</math>)?
 b. fall like a Bloch vector along some angle chosen by vacuum fluctuations?
-Answer: there is no way of telling unless you prepare a specific experiment. If we detect (with unity quantum efficiency) the emitted photons, then each detection projects the system one step down along the Dicke ladder, and <math><D>=0</math>.
+Answer: there is no way of telling unless you prepare a specific experiment. If we detect (with unity quantum efficiency) the emitted photons, then each detection projects the system one step down along the Dicke ladder, and <math>\langle D\rangle=0</math>.
 If we measure the phase of the emitted light, say with some heterodyne technique, then we find that the system evolves as a Bloch state.
+Question2: Is there enhanced induced emission or absorption?
+Answer:No. initial state <math>(|g\rangle)^N</math>, single particle <math>|g\rangle\rightarrow |\psi_1(t)\rangle</math>, N particles  <math>(|g\rangle)^N\rightarrow (|\psi_1(t)\rangle)^N</math>. Consequently, it takes exactly half a Rabi period to completely invert the population as for a single atom. There are N Dicke steps with N times larger matrix elements. In contrast, for spontaneous emission, there are N Dicke steps, with <math>N^2</math> times larger matrix elements <math>\Rightarrow</math> N times faster.
 == Dicke states of extended samples ==
@@ Line 534: / Line 847: @@
 [[Image:26_ExtendedDicke.jpg]]
-such that a preferential mode (along x) is defined. Then we can define Dicke states with respect to that mode as
+such that a preferential mode (along x) is defined. Emission into solid angle <math>\frac{\lambda^2}{A}</math> can be coherent. Thus, the total radiation intensity is enhanced by a factor of about <math>\frac{N\lambda^2}{A}=nAL\frac{\lambda^2}{A}=n\lambda^2 L</math>. This is analogous to optical amplification gain cross section <math>\lambda^2</math>. Formally, we can define Dicke states with respect to the preferred mode as
-<math>|L,M=-L>=|g...g></math>
+<math>|L,M=-L\rangle=|g\cdots g\rangle</math>
-<math>|L,M=-L+1>=\frac{1}{\sqrt {N}}(e^{i k x_1}|eg...g>+e^{ikx_2}|geg...>+...+e^{ikx_N}|g...ge>)</math>
+<math>|L,M=-L+1\rangle=\frac{1}{\sqrt {N}}(e^{i k x_1}|eg\cdots g\rangle+e^{ikx_2}|geg\cdots \rangle+\cdots +e^{ikx_N}|g\cdots ge\rangle)</math>
-<math>|L,M=-L+2>=\frac{\sqrt {2}}{\sqrt {N(N-1)}}|e^{ik x_1}e^{ik x_ 2}|eeg...g>+e^{ik x_1}e^{ikx_ 2}|egeg...>+...</math>
+<math>|L,M=-L+2\rangle=\frac{\sqrt {2}}{\sqrt {N(N-1)}}(e^{ik x_1}e^{ik x_ 2}|eeg\cdots g\rangle+e^{ik x_1}e^{ikx_ 3}|egeg\cdots \rangle+\cdots )</math>
 etc.
@@ Line 563: / Line 876: @@
 == Raman Superradiance ==
-[[Image:26_RamanSuperradiance.jpg]]
+[[Image:26_RamanSuperradiance1.jpg|frame|center|]]
-In the limit of large <math>\Delta </math> and low saturation <math>\omega _1\ll \Delta </math>, we can eliminate the excited state and have an effective system.
+In the limit of large detuning and low saturation <math>\Omega \ll \Delta </math>, we can eliminate the excited state by using the dressed atoms' picture. The dressing beam <math>\Omega</math> is making a two-photon resonance from <math>|g_1\rangle</math> to <math>|g_2\rangle</math>. From another picture, it is also mixing the two levels <math>|e\rangle</math> and <math>|g_2\rangle</math>. If we eliminate the excited state, we will get a effective two level system.
-[[Image:26_RamanEffectiveSystem.jpg|center]]
+[[Image:26_RamanEffectiveSystem1.jpg|center|frame|]]
-<math>\Gamma_{sc}=\frac{\omega _1^2}{\Delta ^2}\frac{r}{2}</math>
+For the mixing level <math>|g_2\rangle</math>, the scattering rate will be <math>\Gamma_{sc}=\frac{\Omega^2}{\Delta ^2}\frac{\Gamma}{2}</math>.
-We can now adjust the linewidth <math>\Gamma_{sc}</math> via <math>\omega _1</math> and also make the excited state <math>|e'></math> suddenly stable by turning off <math>\omega _1</math>. In fact we can switch ground and excited states by applying a laser beam on the other Raman leg instead.
+Now we find We can adjust the linewidth <math>\Gamma_{sc}</math> via <math>\Omega</math> for the effective excited state <math>|g_2\rangle</math>.
 <br style="clear: both" />
@@ Line 577: / Line 890: @@
 == Storing light, catching photons ==
-[[Image:26_StoringLight.jpg]]
+[[Image:26_StoringLight1.jpg|frame|center]]
-When we consider a quantized field on the <math>|g>\rightarrow |e></math> transition, there is a family of dark states, corresponding to <math>n=0,1,2,...</math> excitations
+When we consider a quantized field on the <math>|g_1\rangle\rightarrow |e\rangle</math> transition and a classical control beam connecting <math>|g_2\rangle</math> and <math>|e\rangle</math>, there is a family of dark states for the collective three-levels systems, corresponding to <math>n=0,1,2,\cdots </math> excitations in different spin manifolds for a N photons input state.
-<math>|D,n>=\Sigma ^ n_{k=0}\sqrt {\frac{n!}{k!(n-k)!}}\frac{(-g)^{k }N^{\frac{k }{2}}\Omega ^{n-k }}{(Ng^2+\Omega ^2)^{\frac{n}{2}}}|n-k >_{\mathrm{photons}}|L=\frac{N}{2},M=-L+k ></math>
+<math>|D,n\rangle=\Sigma ^ n_{k=0}\sqrt {\frac{n!}{k!(n-k)!}}\frac{(-g)^{k }N^{\frac{k }{2}}\Omega ^{n-k }}{(Ng^2+\Omega ^2)^{\frac{n}{2}}}|n-k \rangle_{\mathrm{photons}}|L=\frac{N}{2},M=-L+k \rangle</math>
-(Lukin, Yelin, and Fleischhauer PRL 84, 4233 (2000)).
+(Lukin, Yelin, and Fleischhauer PRL 84, 4232 (2000)).
-When <math>\Omega \gg Ng^2</math>, these states are purely photonic. When <math>\omega \ll Ng^2</math>, these states are purely atomic excitations.
+When <math>\Omega^2 \gg Ng^2</math>, these states are purely photonic. When <math>\Omega^2 \ll Ng^2</math>, these states are purely atomic excitations.
 <math>
-\Omega \gg Ng^2 :|D,n> \rightarrow |n>_{\mathrm{photons}}|L,M=-L>_{\mathrm{atoms}}
+\Omega^2 \gg Ng^2 :|D,n\rangle \rightarrow |n\rangle_{\mathrm{photons}}|L,M=-L\rangle_{\mathrm{atoms}}
 </math>
-<math>\Omega \ll Ng^2 : |0>_{\mathrm{photons}}|L,M=-L+n>_{\mathrm{atoms}}</math>
+<math>\Omega^2 \ll Ng^2 : |0>_{\mathrm{photons}}|L,M=-L+n\rangle_{\mathrm{atoms}}</math>
-In general, these excitations n=0,1,2,... are called dark state polaritons. They are a mixture of photonic excitations and spin-wave excitations.
+In general, these excitations <math>n=0,1,2,\cdots </math> are called dark state polaritons. They are a mixture of photonic excitations and spin-wave excitations.
-By adiabatically changing <math>\Sigma \rightarrow 0</math> after the pulse has entered the medium, we can map any photonic state <math>|\psi >_{\mathrm{photon}}=\Sigma c_i|i>_{\mathrm{photon}}</math> onto a spin wave, store it and map it back onto a light-field by turning on the coupling laser <math>\Omega </math> again.
+By adiabatically changing <math>\Omega \rightarrow 0</math> after the pulse has entered the medium, we can map any photonic state <math>|\psi \rangle_{\mathrm{photon}}=\Sigma c_i|i\rangle_{\mathrm{photon}}</math> onto a spin wave, store it and map it back onto a light-field by turning on the coupling laser <math>\Omega </math> again.
 == Notes ==
+[[Old Coherence| Old Coherence Page]]
 [[Category:8.421]]

Difference between revisions of "Coherence"

Latest revision as of 17:11, 24 May 2022

Contents

Introduction

Spontaneous Emission

Coherence in two-level systems

Measuring Coherence

More on the coherence of atoms and light

Precession of a spin in a magnetic field

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

Quantum Beats

Delayed Detection

Three-Level System

Introduction

Optical Pumping

Dark State (On Resonant Case)

Coherent Population Trapping

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

External states: VSCPT

STIRAP

Gain without Inversion

Electromagnetically induced transparency

EIT in the dressed state picture

EIT vs CPT. What's the difference?

Further theoretical treatment

EIT: Eigenstates picture

STIRAP in a three-level system

Example: Five-level non-local STIRAP

On the "magic" of dark-state adiabatic transfer

Two-photon absorption features. Fano profiles

Slow light, adiabatic changes of velocity of light

Superradiance

Superradiance, continued

Supperradiance in N atoms

Dicke states of extended samples

Oscillating and overdamped regimes of superradiance

Raman Superradiance

Storing light, catching photons

Notes

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