Difference between revisions of "Derivation of the optical Bloch equations"
imported>Ichuang |
imported>Zakven (→Putting it together: the optical Bloch equations: Continuing to update \Omega to \omega_R) |
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A good starting point, to appreciate the problem of open quantum | A good starting point, to appreciate the problem of open quantum | ||
systems, is the classical model for a two-level atom coupled to a | systems, is the classical model for a two-level atom coupled to a | ||
− | black-body electromagnetic field, the Einstein rate equations | + | black-body electromagnetic field, the [[Interaction_of_an_atom_with_an_electromagnetic_field#Introduction:_Spontaneous_and_Stimulated_Emission|Einstein rate equations]] |
:<math>\begin{array}{rcl} | :<math>\begin{array}{rcl} | ||
\frac{dN_g}{dt} &=& A_{eg} N_e + u(\omega_{eg}) \left[ { B_{eg}N_e - | \frac{dN_g}{dt} &=& A_{eg} N_e + u(\omega_{eg}) \left[ { B_{eg}N_e - | ||
Line 52: | Line 52: | ||
Hamiltonian dynamics. | Hamiltonian dynamics. | ||
− | ==== Review of density matrices: definition, properties, and | + | ==== Review of density matrices: definition, properties, and unravelings ==== |
Recall that a density matrix <math>\rho</math> for a pure state <math>|\psi{\rangle}</math> is the | Recall that a density matrix <math>\rho</math> for a pure state <math>|\psi{\rangle}</math> is the | ||
Line 96: | Line 96: | ||
statistical mixture of pure states, | statistical mixture of pure states, | ||
:<math> | :<math> | ||
− | \rho = \sum_k p_k |\psi_k{\rangle} | + | \rho = \sum_k p_k |\psi_k{\rangle}\langle\psi_k | |
\,, | \,, | ||
</math> | </math> | ||
− | where <math>p_k</math> are probabilities, such that <math>\sum_k p_k = 1</math> | + | where <math>p_k</math> are probabilities, such that, |
+ | :<math> | ||
+ | \sum_k p_k = 1 | ||
+ | \,. | ||
+ | </math> | ||
A matrix <math>\rho</math> is a valid density matrix if and only if the | A matrix <math>\rho</math> is a valid density matrix if and only if the | ||
Line 126: | Line 130: | ||
classical field Jaynes-Cummings Hamiltonian | classical field Jaynes-Cummings Hamiltonian | ||
:<math> | :<math> | ||
− | H = \frac{\hbar\omega_0}{2}(|e \rangle \langle e|-|g \rangle \langle g|) + \ | + | H = \frac{\hbar\omega_0}{2}(|e \rangle \langle e|-|g \rangle \langle g|) + |
+ | \frac{\hbar\omega_R}{2} (|g \rangle \langle e|+|e \rangle \langle g|) | ||
\,, | \,, | ||
</math> | </math> | ||
which we may express using Pauli matrices as | which we may express using Pauli matrices as | ||
:<math> | :<math> | ||
− | H = \frac{\hbar\omega_0}{2} Z + \ | + | H = \frac{\hbar\omega_0}{2} Z + \frac{\hbar\omega_R}{2} X |
\,, | \,, | ||
</math> | </math> | ||
Line 141: | Line 146: | ||
the equation of motion for <math>\rho</math> is | the equation of motion for <math>\rho</math> is | ||
:<math> | :<math> | ||
− | \dot{\rho} = \left[ \begin{array}{cc}{i\ | + | \dot{\rho} = \left[ \begin{array}{cc}{i\frac{\omega_R}{2}(\rho_{eg}-\rho_{ge})}&{-i\omega_0\rho_{eg}+i\frac{\omega_R}{2}(\rho_{ee}-\rho_{gg})}\\{i\omega_0\rho_{ge}-i\frac{\omega_R}{2}(\rho_{ee}-\rho_{gg})}&{-i\frac{\omega_R}{2}(\rho_{eg}-\rho_{ge})}\end{array}\right] |
\,. | \,. | ||
</math> | </math> | ||
− | We can recognize this as a rotation of the Bloch | + | In terms of the matrix components, this is |
+ | {{Eq | ||
+ | |math=<math>\begin{array}{rcl} | ||
+ | \dot{\rho}_{ee} &=& i\frac{\omega_R}{2}(\rho_{eg}-\rho_{ge}) | ||
+ | \\ | ||
+ | \dot{\rho}_{ge} &=& i\omega_0\rho_{ge} - i\frac{\omega_R}{2}(\rho_{ee}-\rho_{gg}) | ||
+ | \,, | ||
+ | \end{array}</math> | ||
+ | |num=3.1.1 | ||
+ | }} | ||
+ | noting that <math>\rho_{eg}=\rho_{ge}^*</math> and <math>\rho_{gg}=1-\rho_{ee}</math>. | ||
+ | |||
+ | We can recognize this as a rotation of the Bloch vector about the axis | ||
defined by | defined by | ||
:<math> | :<math> | ||
− | \vec{n} = \frac{ | + | \vec{n} = \frac{\omega_0}{2} \hat{z} + \frac{\omega_R}{2} \hat{x} |
\,, | \,, | ||
</math> | </math> | ||
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We can build a mathematical model for quantum open system dynamics, | We can build a mathematical model for quantum open system dynamics, | ||
based on four basic ideas: | based on four basic ideas: | ||
− | + | <table border=1> | |
− | + | <tr> | |
− | + | <td> | |
− | + | Density matrix evolution | |
− | + | </td> | |
+ | <td> | ||
+ | Instead of pure states (eg <math>|\psi{\rangle}</math>), we describe the system | ||
+ | state using a density matrix <math>\rho</math>. The equation of motion | ||
+ | for <math>\rho</math> is | ||
:<math> | :<math> | ||
− | + | \dot{\rho} = { \mathcal L}[ \rho ] | |
\,, | \,, | ||
</math> | </math> | ||
− | + | where <math>{ \mathcal L}</math> is known as the Liouvillian operator (or a | |
− | + | "superoperator"). For example, for Hamiltonian evolution, | |
− | + | we have: | |
:<math> | :<math> | ||
i\hbar \partial_t |\psi \rangle = H |\psi{\rangle} | i\hbar \partial_t |\psi \rangle = H |\psi{\rangle} | ||
Line 182: | Line 203: | ||
\,. | \,. | ||
\end{array}</math> | \end{array}</math> | ||
− | + | This is unitary evolution, but in general, the differential | |
− | + | equation for <math>\rho</math> can describe non-unitary evolution. | |
− | + | Such differential equations are known as "master equations." | |
− | + | They are nontrivial to construct, because they must restrict | |
− | + | <math>\rho</math> to be a legitimate density matrix at all times. | |
− | + | </td></tr> | |
− | + | <tr> | |
− | + | <td> | |
− | + | [[Entangled_Photons#Partial_Traces|Partial trace]] | |
− | + | </td> | |
+ | <td> | ||
+ | We are interested in the state of the system alone, and want | ||
+ | to disregard the state of the environment. If <math>\rho_{\rm | ||
+ | total}</math> is the state of the whole system + environment, then | ||
+ | the state of the system alone is | ||
:<math>\begin{array}{rcl} | :<math>\begin{array}{rcl} | ||
\rho_{sys} &=& {\rm Tr}_{env} \left[ { \rho_{\rm total} } \right] | \rho_{sys} &=& {\rm Tr}_{env} \left[ { \rho_{\rm total} } \right] | ||
\\ &=& \sum_{\rm env} {\langle}{\rm env}| \rho_{\rm total} |{\rm env}{\rangle} | \\ &=& \sum_{\rm env} {\langle}{\rm env}| \rho_{\rm total} |{\rm env}{\rangle} | ||
− | + | \,. | |
\end{array}</math> | \end{array}</math> | ||
− | + | </td></tr> | |
− | + | <tr> | |
− | + | <td> | |
− | + | Assumptions about the environment | |
− | + | </td><td> | |
− | + | The environment is also known as a "bath" or a "reservoir" | |
− | + | (cf API). We model it as being an ensemble of oscillators, of | |
− | + | a variety of frequencies, which are weakly coupled to the | |
− | + | system. It has several important properties: | |
− | + | * Large and unchanging -- Born approximation | |
− | + | * Short correlation time <math>\tau_c</math> -- Markov approximation | |
− | + | </td></tr> | |
− | + | <tr> | |
− | + | <td> | |
− | + | Two (very different) timescales | |
− | + | </td><td> | |
− | + | There are two important timescales in this model: | |
− | + | * <math>T_{relax}</math>: A slow evolution of the system | |
− | + | * <math>\tau_c</math>: The fast fluctuations of the environment | |
− | + | ||
+ | We will build equations of motion which have a timescale | ||
+ | <math>\Delta t</math>, chosen such that <math>\tau_c \ll \Delta t \ll | ||
+ | T_{relax}</math>. | ||
+ | </td></tr> | ||
+ | </table> | ||
+ | |||
Our goal is to construct a model dynamical equation of motion for | Our goal is to construct a model dynamical equation of motion for | ||
<math>\rho_{sys}</math> of the form | <math>\rho_{sys}</math> of the form | ||
Line 229: | Line 261: | ||
we construct a master equation for the atom + vacuum using two | we construct a master equation for the atom + vacuum using two | ||
different approaches. | different approaches. | ||
+ | |||
=== Beamsplitter model of the master equation === | === Beamsplitter model of the master equation === | ||
The physical intuition behind the master equation we desire to | The physical intuition behind the master equation we desire to | ||
construct can be captured with a simple example, which builds on the | construct can be captured with a simple example, which builds on the | ||
− | beamsplitter we studied in previous lectures. Consider a single | + | beamsplitter we studied in previous lectures. |
+ | |||
+ | ==== Single photon through beamsplitter: pure state description ==== | ||
+ | |||
+ | Consider a single | ||
photon state <math>|\psi \rangle = \alpha |0 \rangle + \beta |1{\rangle}</math> (for simplicity, let the | photon state <math>|\psi \rangle = \alpha |0 \rangle + \beta |1{\rangle}</math> (for simplicity, let the | ||
coefficients be real-valued) entering a beamsplitter of angle | coefficients be real-valued) entering a beamsplitter of angle | ||
<math>\theta</math>: | <math>\theta</math>: | ||
− | ::[[Image:chapter4-obe-part-1-obe-fig3.png|thumb| | + | ::[[Image:chapter4-obe-part-1-obe-fig3.png|thumb|400px|none|]] |
+ | |||
A vacuum state <math>|0{\rangle}</math> is input to the other port, whose output we | A vacuum state <math>|0{\rangle}</math> is input to the other port, whose output we | ||
discard. Let us consider the photon as being our system, and the | discard. Let us consider the photon as being our system, and the | ||
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<math>p_1 = \beta ^2 \sin^2 \theta</math>, so that we might expect the output to be | <math>p_1 = \beta ^2 \sin^2 \theta</math>, so that we might expect the output to be | ||
<math>|0{\rangle}</math> with probability <math>p_1</math>, and <math>|\psi{\rangle}</math> with probability <math>1-p_1</math>. | <math>|0{\rangle}</math> with probability <math>p_1</math>, and <math>|\psi{\rangle}</math> with probability <math>1-p_1</math>. | ||
+ | |||
However, that (semi-)classical argument is incorrect. | However, that (semi-)classical argument is incorrect. | ||
The output state <math>|\phi{\rangle}</math> of the system + environment is | The output state <math>|\phi{\rangle}</math> of the system + environment is | ||
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( \alpha |0 \rangle + \beta \cos\theta |1 \rangle )/\sqrt{ \alpha ^2 + \beta ^2 \cos^2\theta}</math>, with | ( \alpha |0 \rangle + \beta \cos\theta |1 \rangle )/\sqrt{ \alpha ^2 + \beta ^2 \cos^2\theta}</math>, with | ||
probability <math>1-p_1</math>, and <math>|\psi_1 \rangle = |0{\rangle}</math> with probability <math>p_1</math>. | probability <math>1-p_1</math>, and <math>|\psi_1 \rangle = |0{\rangle}</math> with probability <math>p_1</math>. | ||
+ | |||
+ | |||
+ | ==== Single photon through beamsplitter: density matrix description ==== | ||
+ | |||
These states can conveniently be written as density matrices. The | These states can conveniently be written as density matrices. The | ||
input state is | input state is | ||
− | + | {{Eq | |
+ | |math=<math> | ||
\rho_{in} = |\psi{\rangle}{\langle}\psi| = \left[ \begin{array}{cc}{ \alpha ^2}&{ \alpha \beta }\\{ \alpha \beta }&{ \beta ^2}\end{array}\right] | \rho_{in} = |\psi{\rangle}{\langle}\psi| = \left[ \begin{array}{cc}{ \alpha ^2}&{ \alpha \beta }\\{ \alpha \beta }&{ \beta ^2}\end{array}\right] | ||
\,, | \,, | ||
− | |||
</math> | </math> | ||
+ | |num=3.3.1 | ||
+ | }} | ||
and the output state is | and the output state is | ||
:<math>\begin{array}{rcl} | :<math>\begin{array}{rcl} | ||
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\,. | \,. | ||
\end{array}</math> | \end{array}</math> | ||
+ | |||
Note that <math>\rho_{out}</math> cannot be written as <math>|\chi{\rangle}{\langle}\chi|</math> for any | Note that <math>\rho_{out}</math> cannot be written as <math>|\chi{\rangle}{\langle}\chi|</math> for any | ||
pure state <math>|\chi{\rangle}</math>, because it is not pure (it is a statistical mixture). | pure state <math>|\chi{\rangle}</math>, because it is not pure (it is a statistical mixture). | ||
Line 278: | Line 324: | ||
\,. | \,. | ||
</math> | </math> | ||
+ | |||
+ | ==== Single photon through many beamsplitters: coarse-grained evolution ==== | ||
+ | |||
Now imagine that we send the single photon state through many | Now imagine that we send the single photon state through many | ||
beamsplitters in a sequence, each with some small tap angle <math>\theta = | beamsplitters in a sequence, each with some small tap angle <math>\theta = | ||
\sqrt{\Gamma \Delta t/2}</math>: | \sqrt{\Gamma \Delta t/2}</math>: | ||
− | ::[[Image:chapter4-obe-part-1-obe-fig4.png|thumb| | + | ::[[Image:chapter4-obe-part-1-obe-fig4.png|thumb|400px|none|]] |
− | + | ||
We make two assumptions: the environment modes always begin in the | We make two assumptions: the environment modes always begin in the | ||
vacuum <math>|0{\rangle}</math> (this is the Born approximation), and the environment is | vacuum <math>|0{\rangle}</math> (this is the Born approximation), and the environment is | ||
completely different and uncorrelated between scattering events (this | completely different and uncorrelated between scattering events (this | ||
is the Markov approximation). | is the Markov approximation). | ||
+ | |||
This allows us to write a coarse-grained differential equation for the | This allows us to write a coarse-grained differential equation for the | ||
photon state | photon state | ||
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</math> | </math> | ||
Expressed as differential equations for each of the independent matrix | Expressed as differential equations for each of the independent matrix | ||
− | elements, we get (using Eq.( | + | elements, we get (using Eq.(3.3.1) for <math>\rho(t=0)</math>) |
:<math>\begin{array}{rcl} | :<math>\begin{array}{rcl} | ||
\frac{d}{dt} \rho_{00} &=& +\Gamma \rho_{11} | \frac{d}{dt} \rho_{00} &=& +\Gamma \rho_{11} | ||
\\ \frac{d}{dt} \rho_{11} &=& -\Gamma \rho_{11} | \\ \frac{d}{dt} \rho_{11} &=& -\Gamma \rho_{11} | ||
\end{array}</math> | \end{array}</math> | ||
− | for the diagonal elements. These describe the evolutions of the | + | for the diagonal elements. |
+ | |||
+ | These describe the evolutions of the | ||
probabilities of finding the photon in the <math>|0{\rangle}</math> and <math>|1{\rangle}</math> states, | probabilities of finding the photon in the <math>|0{\rangle}</math> and <math>|1{\rangle}</math> states, | ||
and are analogous to the Einstein rate equations. And for the | and are analogous to the Einstein rate equations. And for the | ||
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\end{array}</math> | \end{array}</math> | ||
which show the decay of the quantum coherence of the state. | which show the decay of the quantum coherence of the state. | ||
+ | |||
+ | Note that the input state we have used in this model is a pure state, but essentially the same result holds if the input is a general mixed state. Specifically, if the input were an arbitrary density matrix | ||
+ | :<math> | ||
+ | \rho = \left[ \begin{array}{cc}a&b\\c&d\end{array}\right] | ||
+ | </math> | ||
+ | then the coarse-grained differential equation for this input would be | ||
+ | {{Eq | ||
+ | |math=<math> | ||
+ | \dot{\rho} = -\frac{\Gamma}{2} \left[ \begin{array}{cc}{ 2 a}&{b}\\{c}&{-2a}\end{array}\right] | ||
+ | \,, | ||
+ | </math> | ||
+ | |num=3.3.2 | ||
+ | }} | ||
+ | |||
+ | ==== Comparison to the general master equation ==== | ||
+ | |||
The form of these differential equations, which are master equations, | The form of these differential equations, which are master equations, | ||
is very general, and almost exactly the same result is obtained for a | is very general, and almost exactly the same result is obtained for a | ||
− | two-level atom interacting with the vacuum. In that | + | two-level atom interacting with the vacuum. In particular, we shall see that in the master equation for a two-level atom undergoing spontaneous emission, the coherences (the off-diagonal terms) decay twice as fast as the populations (the diagonal terms). That essential physics is captured perfectly by the beamsplitter model, namely Eq.(3.3.2). |
− | + | ||
+ | There are differences in the atomic master equation, however. In particular,the coherences evolve as | ||
:<math>\begin{array}{rcl} | :<math>\begin{array}{rcl} | ||
\frac{d}{dt} \rho_{01} &=& - \left( { i\Delta + \frac{\Gamma}{2}} \right) \rho_{01} | \frac{d}{dt} \rho_{01} &=& - \left( { i\Delta + \frac{\Gamma}{2}} \right) \rho_{01} | ||
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where <math>\Delta</math> is a frequency shift of the system known as the "Lamb | where <math>\Delta</math> is a frequency shift of the system known as the "Lamb | ||
shift," which is due to virtual excitations to higher atomic levels. | shift," which is due to virtual excitations to higher atomic levels. | ||
+ | |||
In the atomic master equation, <math>\Gamma</math> is the spontaneous emission | In the atomic master equation, <math>\Gamma</math> is the spontaneous emission | ||
rate, given by Fermi's golden rule | rate, given by Fermi's golden rule | ||
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\,, | \,, | ||
</math> | </math> | ||
− | as derived | + | as derived [[Lineshape|elsewhere]]. |
+ | |||
=== Full derivation -- walk-through === | === Full derivation -- walk-through === | ||
We now turn to a full derivation of the general master equation. | We now turn to a full derivation of the general master equation. | ||
+ | |||
+ | ==== Master equation in integral form for arbitrary interaction ==== | ||
+ | |||
Following the notation used in API, Chapter 4, let <math>A</math> denote the | Following the notation used in API, Chapter 4, let <math>A</math> denote the | ||
system, and <math>R</math> the environment (known as the reservoir in API). The | system, and <math>R</math> the environment (known as the reservoir in API). The | ||
Line 342: | Line 416: | ||
interaction picture defined by <math>H_A</math> and <math>H_R</math>, the equation of motion | interaction picture defined by <math>H_A</math> and <math>H_R</math>, the equation of motion | ||
for the full system + reservoir density matrix is | for the full system + reservoir density matrix is | ||
− | + | {{Eq | |
+ | |math= | ||
+ | <math> | ||
i\hbar \dot{\rho} = [V,\rho] | i\hbar \dot{\rho} = [V,\rho] | ||
\,. | \,. | ||
− | |||
</math> | </math> | ||
+ | |num=3.5.1 | ||
+ | }} | ||
Integrating this once gives | Integrating this once gives | ||
:<math> | :<math> | ||
Line 352: | Line 429: | ||
\,. | \,. | ||
</math> | </math> | ||
− | Substituting this back into Eq.( | + | Substituting this back into Eq.(3.5.1) gives |
:<math> | :<math> | ||
\dot{\rho} = -\frac{1}{\hbar^2} \int_0^t [V(t),[V(t'),\rho(t')]]\,dt' | \dot{\rho} = -\frac{1}{\hbar^2} \int_0^t [V(t),[V(t'),\rho(t')]]\,dt' | ||
Line 365: | Line 442: | ||
</math> | </math> | ||
This gives us our starting point for a general master equation: | This gives us our starting point for a general master equation: | ||
− | + | {{Eq | |
+ | |math=<math> | ||
\dot{\rho}_{A} | \dot{\rho}_{A} | ||
= -\frac{1}{\hbar^2} {\rm Tr}_R | = -\frac{1}{\hbar^2} {\rm Tr}_R | ||
\int_0^t [V(t),[V(t'),\rho_A(t') \otimes \rho_R ]]\,dt' | \int_0^t [V(t),[V(t'),\rho_A(t') \otimes \rho_R ]]\,dt' | ||
\,. | \,. | ||
− | |||
</math> | </math> | ||
+ | |num=3.5.2 | ||
+ | }} | ||
+ | |||
+ | ==== Master equation for a two-level atom interacting with the vacuum ==== | ||
+ | |||
An example is helpful in seeing how this equation works. Generally, | An example is helpful in seeing how this equation works. Generally, | ||
we will take system + reservoir interactions of the form <math>V = -A R</math>, | we will take system + reservoir interactions of the form <math>V = -A R</math>, | ||
Line 392: | Line 474: | ||
\,. | \,. | ||
</math> | </math> | ||
− | Insert this now into Eq.( | + | Insert this now into Eq.(3.5.2), but disregard the integral |
over time (this lets us see what the essential dynamics are, at the | over time (this lets us see what the essential dynamics are, at the | ||
expense of not obtaining the correct specific rates). The | expense of not obtaining the correct specific rates). The | ||
Line 412: | Line 494: | ||
states, and thus disappear in the partial trace over the reservoir. | states, and thus disappear in the partial trace over the reservoir. | ||
We find, finally: | We find, finally: | ||
− | + | {{Eq | |
+ | |math=<math> | ||
\dot{\rho}_{A} = -\frac{\Gamma}{2} \left[ { \sigma_+ \sigma_- \rho_A - 2 \sigma_- \rho_A \sigma_+ | \dot{\rho}_{A} = -\frac{\Gamma}{2} \left[ { \sigma_+ \sigma_- \rho_A - 2 \sigma_- \rho_A \sigma_+ | ||
+ \rho_A \sigma_+ \sigma_- } \right] | + \rho_A \sigma_+ \sigma_- } \right] | ||
\,. | \,. | ||
</math> | </math> | ||
+ | |num=3.6.1 | ||
+ | }} | ||
This is the master equation for a two-level atom dipole coupled to a | This is the master equation for a two-level atom dipole coupled to a | ||
single electromagnetic mode initially in the vacuum state. It is | single electromagnetic mode initially in the vacuum state. It is | ||
written in a form known as the "Lindblad" form, which is very | written in a form known as the "Lindblad" form, which is very | ||
common. In atomic physics, you will often see master equations like | common. In atomic physics, you will often see master equations like | ||
− | this. The Lindblad form has the special property that it ensures | + | this. |
+ | |||
+ | The Lindblad form has the special property that it ensures | ||
<math>\rho</math> is a legitimate density matrix at all times; not only does | <math>\rho</math> is a legitimate density matrix at all times; not only does | ||
<math>{\rm Tr}(\rho)=1</math> always, but also, its eigenvalues remain | <math>{\rm Tr}(\rho)=1</math> always, but also, its eigenvalues remain | ||
Line 435: | Line 522: | ||
then we find | then we find | ||
:<math> | :<math> | ||
− | \dot{\rho}_A = -\Gamma \left[ \begin{array}{cc}{ 2 a}&{b}\\{c}&{-2a}\end{array}\right] | + | \dot{\rho}_A = -\frac{\Gamma}{2} \left[ \begin{array}{cc}{ 2 a}&{b}\\{c}&{-2a}\end{array}\right] |
\,, | \,, | ||
</math> | </math> | ||
which is identical to the master equation we constructed for the | which is identical to the master equation we constructed for the | ||
− | beamsplitter example, Eq.( | + | beamsplitter example, Eq.(3.3.2), up to a relabeling of <math>|g{\rangle}</math> |
and <math>|e{\rangle}</math>. | and <math>|e{\rangle}</math>. | ||
+ | |||
As shown by this example, the physical picture behind the master | As shown by this example, the physical picture behind the master | ||
equation is not so complicated, even though the mathematics (used in | equation is not so complicated, even though the mathematics (used in | ||
all its glory) can be overwhelming. | all its glory) can be overwhelming. | ||
+ | |||
+ | ==== Putting it together: the optical Bloch equations ==== | ||
+ | |||
The equation of motion for <math>\dot{\rho}</math> we have obtained is very close | The equation of motion for <math>\dot{\rho}</math> we have obtained is very close | ||
to the classical Einstein equations we began with, as we can see by | to the classical Einstein equations we began with, as we can see by | ||
writing out equations of motion for the individual components of | writing out equations of motion for the individual components of | ||
<math>\rho</math>. Explicitly, and including Hamiltonian evolution under the | <math>\rho</math>. Explicitly, and including Hamiltonian evolution under the | ||
− | classical field Jaynes-Cummings interaction, we find | + | classical field Jaynes-Cummings interaction, Eq.(3.1.1), we find |
:<math>\begin{array}{rcl} | :<math>\begin{array}{rcl} | ||
− | \dot{\ | + | \dot{\rho}_{ee} &=& i\frac{\omega_R}{2}(\rho_{eg}-\rho_{ge}) - \Gamma \rho_{ee} |
\\ | \\ | ||
− | \dot{\ | + | \dot{\rho}_{ge} &=& i\omega_0\rho_{ge} - i\frac{\omega_R}{2}(\rho_{ee}-\rho_{gg}) |
- \frac{\Gamma}{2} \rho_{ge} | - \frac{\Gamma}{2} \rho_{ge} | ||
\,, | \,, | ||
\end{array}</math> | \end{array}</math> | ||
− | where the other two components are given by <math>\rho_{gg}=1-\ | + | where the other two components are given by <math>\rho_{gg}=1-\rho_{ee}</math> and |
<math>\rho_{eg} = \rho_{ge}^*</math>. These differential equations are known as | <math>\rho_{eg} = \rho_{ge}^*</math>. These differential equations are known as | ||
the Optical Bloch Equations, and we will base a great deal of | the Optical Bloch Equations, and we will base a great deal of |
Latest revision as of 20:45, 24 March 2017
The master equation is an equation of motion for a density matrix describing an open quantum system, much like the Schrodinger equation describes the evolution of a closed quantum system. This section provides a derivation of the master equation for a spontaneously emitting atom, driven by a classical field, which is known as the Optical Bloch Equation.
Contents
Classical model of atom and field
A good starting point, to appreciate the problem of open quantum systems, is the classical model for a two-level atom coupled to a black-body electromagnetic field, the Einstein rate equations
where is the spontaneous emission rate, and are stimulated emission rates, and is the field energy density at atomic frequency , for levels denoted by and .
Is there a straightforward quantum analogue of this? We might be tempted to simply add a damping term to the Schrödinger equation, like
but this is not physically allowed by quantum mechanics! How, then, can we construct a fully quantum-mechanical description of open system dynamics? The key concept is that we must properly account for noise:
From classical thermodynamics, we know that any time there is energy transfer from a system to the environment, there is entropy exchanged back from the environment to the system. This is a simple illustration of the very basic fluctuation--dissipation principle: there can be no relaxation without con-commitment noise! To study quantum open system, we must model the appropriate quantum noise contribution which goes along with relaxation.
Density matrices and closed system dynamics
The main tool we shall use to model open quantum systems is the density matrix representation for quantum states, so it is helpful to begin with a review of density matrices and how they evolve under Hamiltonian dynamics.
Review of density matrices: definition, properties, and unravelings
Recall that a density matrix for a pure state is the matrix . Thus, for example
Density matrices may also represent statistical mixtures of pure states; this state
can be interpreted as a 50/50 mixture of and . However, one must be careful, because there are infinitely many ways to unravel a density matrix into statistical mixtures of pure states.
For example,
is
but it is also
where
In general, a density matrix may always be written as a statistical mixture of pure states,
where are probabilities, such that,
A matrix is a valid density matrix if and only if the eigenvalues of are non-negative, and sum to one, such that . represents a pure state if and only if .
Density matrices: closed system evolution
How does a density matrix evolve in a closed system? From the Schrodinger equation
it follows that a pure state density matrix evolves as
For example, if is a two-level atom evolving under the classical field Jaynes-Cummings Hamiltonian
which we may express using Pauli matrices as
then for
the equation of motion for is
In terms of the matrix components, this is
(3.1.1)
noting that and .
We can recognize this as a rotation of the Bloch vector about the axis defined by
by using the Bloch sphere representation for a density matrix,
Density matrices and open system dynamics: approach
We can build a mathematical model for quantum open system dynamics, based on four basic ideas:
Density matrix evolution |
Instead of pure states (eg ), we describe the system state using a density matrix . The equation of motion for is where is known as the Liouvillian operator (or a "superoperator"). For example, for Hamiltonian evolution, we have: which, for gives This is unitary evolution, but in general, the differential equation for can describe non-unitary evolution. Such differential equations are known as "master equations." They are nontrivial to construct, because they must restrict to be a legitimate density matrix at all times. |
We are interested in the state of the system alone, and want to disregard the state of the environment. If is the state of the whole system + environment, then the state of the system alone is | |
Assumptions about the environment |
The environment is also known as a "bath" or a "reservoir" (cf API). We model it as being an ensemble of oscillators, of a variety of frequencies, which are weakly coupled to the system. It has several important properties:
|
Two (very different) timescales |
There are two important timescales in this model:
We will build equations of motion which have a timescale , chosen such that . |
Our goal is to construct a model dynamical equation of motion for of the form
where is time independent. This is known as a "coarse grained" evolution equation. It is desirable to obtain for a variety of scenarios, including interactions where the system + environment are atom + light, light + light, and atom + motion, for example. Below, we construct a master equation for the atom + vacuum using two different approaches.
Beamsplitter model of the master equation
The physical intuition behind the master equation we desire to construct can be captured with a simple example, which builds on the beamsplitter we studied in previous lectures.
Single photon through beamsplitter: pure state description
Consider a single photon state (for simplicity, let the coefficients be real-valued) entering a beamsplitter of angle :
A vacuum state is input to the other port, whose output we discard. Let us consider the photon as being our system, and the other (initially vacuum) mode as being our environment. What is the quantum state of the undiscarded output? Naively, we might argue that a single photon is discarded into the environment with probability , so that we might expect the output to be with probability , and with probability .
However, that (semi-)classical argument is incorrect. The output state of the system + environment is
Thus, the correct result is that the output is , with probability , and with probability .
Single photon through beamsplitter: density matrix description
These states can conveniently be written as density matrices. The input state is
(3.3.1)
and the output state is
Note that cannot be written as for any pure state , because it is not pure (it is a statistical mixture). The change in is
Single photon through many beamsplitters: coarse-grained evolution
Now imagine that we send the single photon state through many beamsplitters in a sequence, each with some small tap angle :
We make two assumptions: the environment modes always begin in the vacuum (this is the Born approximation), and the environment is completely different and uncorrelated between scattering events (this is the Markov approximation).
This allows us to write a coarse-grained differential equation for the photon state
Expressed as differential equations for each of the independent matrix elements, we get (using Eq.(3.3.1) for )
for the diagonal elements.
These describe the evolutions of the probabilities of finding the photon in the and states, and are analogous to the Einstein rate equations. And for the off-diagonal elements we get
which show the decay of the quantum coherence of the state.
Note that the input state we have used in this model is a pure state, but essentially the same result holds if the input is a general mixed state. Specifically, if the input were an arbitrary density matrix
then the coarse-grained differential equation for this input would be
(3.3.2)
Comparison to the general master equation
The form of these differential equations, which are master equations, is very general, and almost exactly the same result is obtained for a two-level atom interacting with the vacuum. In particular, we shall see that in the master equation for a two-level atom undergoing spontaneous emission, the coherences (the off-diagonal terms) decay twice as fast as the populations (the diagonal terms). That essential physics is captured perfectly by the beamsplitter model, namely Eq.(3.3.2).
There are differences in the atomic master equation, however. In particular,the coherences evolve as
where is a frequency shift of the system known as the "Lamb shift," which is due to virtual excitations to higher atomic levels.
In the atomic master equation, is the spontaneous emission rate, given by Fermi's golden rule
as derived elsewhere.
Full derivation -- walk-through
We now turn to a full derivation of the general master equation.
Master equation in integral form for arbitrary interaction
Following the notation used in API, Chapter 4, let denote the system, and the environment (known as the reservoir in API). The full Hamiltonian is
where is the system-reservoir interaction potential. In the interaction picture defined by and , the equation of motion for the full system + reservoir density matrix is
(3.5.1)
Integrating this once gives
Substituting this back into Eq.(3.5.1) gives
If we assume that the system and reservoir are initially uncorrelated, and make the approximation that the reservoir stays unchanged (the Born approximation), then
This gives us our starting point for a general master equation:
(3.5.2)
Master equation for a two-level atom interacting with the vacuum
An example is helpful in seeing how this equation works. Generally, we will take system + reservoir interactions of the form , where acts only on the system, and acts only on the reservoir. Specifically, let the system be a two-level atom, and the environment be a single electromagnetic mode initially in the vacuum state . The atom interacts with the usual dipole interaction,
which is conveniently written using Pauli raising and lowering operators
where
Insert this now into Eq.(3.5.2), but disregard the integral over time (this lets us see what the essential dynamics are, at the expense of not obtaining the correct specific rates). The relevant commutators are
and
where the "other" terms are not diagonal in the electromagnetic mode states, and thus disappear in the partial trace over the reservoir. We find, finally:
(3.6.1)
This is the master equation for a two-level atom dipole coupled to a single electromagnetic mode initially in the vacuum state. It is written in a form known as the "Lindblad" form, which is very common. In atomic physics, you will often see master equations like this.
The Lindblad form has the special property that it ensures is a legitimate density matrix at all times; not only does always, but also, its eigenvalues remain non-negative. And more importantly, the map from to is completely positive, meaning that if the map operates on just part of a larger system, the state of the larger system remains described by a valid, positive density matrix. Using the definitions for , if we express as
then we find
which is identical to the master equation we constructed for the beamsplitter example, Eq.(3.3.2), up to a relabeling of and .
As shown by this example, the physical picture behind the master equation is not so complicated, even though the mathematics (used in all its glory) can be overwhelming.
Putting it together: the optical Bloch equations
The equation of motion for we have obtained is very close to the classical Einstein equations we began with, as we can see by writing out equations of motion for the individual components of . Explicitly, and including Hamiltonian evolution under the classical field Jaynes-Cummings interaction, Eq.(3.1.1), we find
where the other two components are given by and . These differential equations are known as the Optical Bloch Equations, and we will base a great deal of our study of atoms and light forces on this quantum description of open system dynamics of a spontaneously emitting atom driven by a classical field.