Difference between revisions of "Resonances"

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= Resonances and Two-Level Atoms =
+
== Classical Resonances ==
== Introduction to Resonances and Precision Measurements ==
+
=== Introduction ===
 +
<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>
 +
 
 
Classically, a resonance is a system where one or more variables
 
Classically, a resonance is a system where one or more variables
 
change periodically such that when the system is no longer driven
 
change periodically such that when the system is no longer driven
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frequency corresponding to the maximum response of the system is
 
frequency corresponding to the maximum response of the system is
 
called the resonance frequency (<math>f_0</math>)
 
called the resonance frequency (<math>f_0</math>)
\begin{figure}
+
 
 
<blockquote>
 
<blockquote>
::[[Image:resonances-example-resonances.png|thumb|400px|none|]]
+
<figure id="fig:example_resonances">
\caption{A resonance in the time (left) and frequency (right) domains.  The
+
[[Image:resonances-example-resonances.png|thumb|400px|none|]]
time domain picture shows the (decaying) oscillation in some variable of the
+
<caption> A resonance in the time (left) and frequency (right) domains.  The time domain picture shows the (decaying) oscillation in some variable of the undriven system, while the frequency-domain pictures shows the steady-state response amplitude of the driven system.  The time units are chosen such that <math>f_0 = \omega_0 / 2 \pi = 1</math> while the quality factor is <math>Q = 10</math>.
undriven system, while the frequency-domain pictures shows the steady-state
+
</caption>
response amplitude of the driven system.  The time units are chosen such that
+
</figure>
<math>f_0 = \omega_0 / 2 \pi = 1</math> while the quality factor is <math>Q = 10</math>.}
 
 
 
</blockquote>
 
</blockquote>
\end{figure}
+
 
 
The simplest resonance systems have a single resonance frequency, corresponding
 
The simplest resonance systems have a single resonance frequency, corresponding
 
to the harmonic motion of the variable.  Some form of dissipation (damping)
 
to the harmonic motion of the variable.  Some form of dissipation (damping)
Line 30: Line 30:
 
superposition of different frequency components, giving the resonance curve a
 
superposition of different frequency components, giving the resonance curve a
 
finite width in frequency space.  Low dissipation results in a long decay time
 
finite width in frequency space.  Low dissipation results in a long decay time
<math>\Delta t</math>, and a narrow frequency width <math>f_0</math>.  The ratio of frequency width
+
<math>\Delta t</math>, and a narrow frequency width <math>\Delta f</math>.  The ratio of frequency width
 
<math>\Delta f</math> to resonance frequency <math>f_0</math> is called the quality factor <math>Q</math>.
 
<math>\Delta f</math> to resonance frequency <math>f_0</math> is called the quality factor <math>Q</math>.
 
:<math>
 
:<math>
Line 42: Line 42:
 
:<math>
 
:<math>
 
   \frac{f_0}{\Delta f}
 
   \frac{f_0}{\Delta f}
   \sim \frac{\unit{10^{15}}{\hertz}}{\unit{10^9}{\hertz}}
+
   \sim \frac{{10^{15}}{\rm Hz}}{{{10^9}\,{{\rm Hz}}}}
 
   \sim 10^6
 
   \sim 10^6
 
</math>
 
</math>
Line 48: Line 48:
 
temperatures: typical <math>Q</math> factors of mechanical or electrical
 
temperatures: typical <math>Q</math> factors of mechanical or electrical
 
systems are <math>\sim 10^3</math> at room temperature and <math>\sim 10^6</math> at
 
systems are <math>\sim 10^3</math> at room temperature and <math>\sim 10^6</math> at
<math>\lesssim \unit{1}{\kelvin}</math> temperatures. Solid optical resonators are an
+
<math>\lesssim {{1}\,{{\rm K}}}</math> temperatures.
exception to this: <math>Q\gtrsim 10^8</math> has been achieved in the whispering gallery
+
 
modes of spheres or cylinders of high-purity glass \cite{Armani2003}.
+
High Q values are obtained in solids acting as optical resonators: <math>Q\gtrsim 10^8</math> has been achieved in the whispering gallery modes of spheres or cylinders of high-purity glass <ref name="Armani2003">D. K. Armani, T. J. Kippenberg, S. M. Spillane, and K. J. Vahala. Ultra-high-Q toroid microcavity on a chip. Nature, 421:925–928, Feb 2003.</ref>.
\begin{figure}
+
 
 
<blockquote>
 
<blockquote>
::[[Image:resonances-whispering-gallery|thumb|400px|none|]]
+
::[[Image:resonances-whispering-gallery.png|thumb|400px|none|]]
  \caption{One of the whispering-gallery resonators described in
+
One of the whispering-gallery resonators described in
  \cite{Armani2003}.  This particular resonator had a quality factor <math>Q=10^8</math>.
+
<ref name="Armani2003">D. K. Armani, T. J. Kippenberg, S. M. Spillane, and K. J. Vahala. Ultra-high-Q toroid microcavity on a chip. Nature, 421:925–928, Feb 2003.</ref>.  This particular resonator had a quality factor <math>Q=10^8</math>.
  The very high surface quality required for such low losses is achieved by
+
The very high surface quality required for such low losses is achieved by
  having surface tension shape the rim of the disk after it has been temporarily
+
having surface tension shape the rim of the disk after it has been temporarily
  liquefied by a laser pulse; the inset shows the resonator before this
+
liquefied by a laser pulse; the inset shows the resonator before this
  treatment.}
+
treatment.
 
 
 
</blockquote>
 
</blockquote>
\end{figure}
+
 
 
At the macroscopic scale, astronomical systems consisting of massive bodies
 
At the macroscopic scale, astronomical systems consisting of massive bodies
 
travelling essentially undisturbed through the near-vacuum of space can also
 
travelling essentially undisturbed through the near-vacuum of space can also
exhibit high <math>Q</math> factors.
+
exhibit high <math>Q</math> factors. The rotation of the earth has a <math>Q</math> value of <math>10^7</math>, and pulsars of <math>10^{10}</math>.
 +
 
 
A resonance is particularly useful for science and technology if it is
 
A resonance is particularly useful for science and technology if it is
 
reproducible by different realizations of the same system, and if it has a
 
reproducible by different realizations of the same system, and if it has a
Line 75: Line 75:
 
frequencies of hydrogen, and to a lesser degree helium, are directly tied via
 
frequencies of hydrogen, and to a lesser degree helium, are directly tied via
 
quantum mechanics to fundamental constants such as the Rydberg constant,
 
quantum mechanics to fundamental constants such as the Rydberg constant,
<math>R_\infty=\unit{1.0973731568525(73)\times10^7}{\reciprocal\metre}</math>
+
<math>R_\infty={{1.0973731568525(73)\times10^7}\,{{\rm m}^{-1}}}</math>
\cite{codata2002}, or the fine structure constant <math>\alpha=1/137.03599911(46)</math>
+
<ref name="codata2002">Peter J. Mohr, Barry N. Taylor, and David B. Newell. CODATA recommended values of the fundamental physical constants: 2002. Rev. Mod. Phys., 77, Jan 2005. Available online at http://physics.nist.gov/constants.</ref>, or the fine structure constant <math>\alpha=1/137.03599911(46)</math>
\cite{codata2002}.  In fact, the Rydberg constant is the most accurately known
+
<ref name="codata2002">Peter J. Mohr, Barry N. Taylor, and David B. Newell. CODATA recommended values of the fundamental physical constants: 2002. Rev. Mod. Phys., 77, Jan 2005. Available online at http://physics.nist.gov/constants.</ref>.  In fact, the Rydberg constant is the most accurately known
 
constant in all of physics, and most fundamental constants have been determined
 
constant in all of physics, and most fundamental constants have been determined
 
by atomic physics or optical techniques.  Additional motivation for measuring
 
by atomic physics or optical techniques.  Additional motivation for measuring
 
fundamental constants with ever-increasing accuracy has been provided by the
 
fundamental constants with ever-increasing accuracy has been provided by the
speculation (and claims of evidence for it \cite{Flambaum2004,Reinhold2006}),
+
speculation (and claims of evidence for it <ref name="Flambaum2004">V. V. Flambaum, D. B. Leinweber, A. W. Thomas, and R. D. Young. Limits on variations of the quark masses, QCD scale, and fine structure constant. Phys. Rev. D, 69(11):115006, 2004.</ref><ref name="Reinhold2006">E. Reinhold, R. Buning, U. Hollenstein, A. Ivanchik, P. Petitjean, and W. Ubachs. Indication of a cosmological variation of the proton-electron mass ratio based on laboratory measurement and reanalysis of h2 spectra. Phys. Rev. Lett., 96:151101, 2006.</ref>),
 
that the fundamental constants may not be so constant after all, but that their
 
that the fundamental constants may not be so constant after all, but that their
 
value is tied to the evolution (and therefore the age) of the universe.
 
value is tied to the evolution (and therefore the age) of the universe.
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indicated the need for new theories or modifications of theories.  For instance,
 
indicated the need for new theories or modifications of theories.  For instance,
 
"anomalous" effects in the Zeeman structure (magnetic-field dependance) of
 
"anomalous" effects in the Zeeman structure (magnetic-field dependance) of
atomic lines led to the discovery of spin \cite{Uhlenbeck1926}.
+
atomic lines led to the discovery of spin <ref name="Uhlenbeck1926">G. E. Uhlenbeck and S. Goudsmit. Spinning electrons and the structure of spectra. Nature, 117(2938):264, Feb 1926.</ref>.
 
while Lamb's measurement of the splitting between the <math>^2S_{1/2}</math> and
 
while Lamb's measurement of the splitting between the <math>^2S_{1/2}</math> and
<math>^2P_{1/2}</math> states of atomic hydrogen, on the order of \unit{1000}{\mega\hertz}
+
<math>^2P_{1/2}</math> states of atomic hydrogen, on the order of 1000MHz instead of 0 as predicted by the Dirac theory,  fostered the development of quantum electrodynamics, the quantum theory of light.
instead of 0 as predicted by the Dirac theory,  fostered the development of
+
 
quantum electrodynamics, the quantum theory of light.
+
<!-- comment -->
== Classical Resonances ==
+
 
 +
=== Classical Harmonic Oscillator ===
 
A classical harmonic oscillator (HO) is a system
 
A classical harmonic oscillator (HO) is a system
 
described by the second order differential equation
 
described by the second order differential equation
Line 98: Line 99:
 
   \ddot{q}+\gamma \dot{q}+\omega_0^2 q = 0
 
   \ddot{q}+\gamma \dot{q}+\omega_0^2 q = 0
 
</math>
 
</math>
such as a mass on a spring, or a charge, voltage, or currant in an electric RLC
+
such as a mass on a spring, or a charge, voltage, or current in an electric RLC
 
resonant circuit.  For weak damping (<math>\gamma^2 < 4\omega_0^2</math>) the undriven
 
resonant circuit.  For weak damping (<math>\gamma^2 < 4\omega_0^2</math>) the undriven
 
system decays with an exponential envelope,
 
system decays with an exponential envelope,
Line 117: Line 118:
 
</math>
 
</math>
 
where <math>\Delta=\omega-\omega_0</math> is the detuning as shown on the right-hand side
 
where <math>\Delta=\omega-\omega_0</math> is the detuning as shown on the right-hand side
of Figure \ref{fig:example_resonances}.  The full width at half maximum (FWHM)
+
of <xr id="fig:example_resonances"/>.  The full width at half maximum (FWHM)
 
of a lorentzian curve is <math>\Delta \omega=\gamma</math> leading to a quality factor
 
of a lorentzian curve is <math>\Delta \omega=\gamma</math> leading to a quality factor
 
:<math>
 
:<math>
Line 126: Line 127:
 
should not be confused with frequencies <math>f_0=\omega_0/2\pi</math>, <math>\Delta
 
should not be confused with frequencies <math>f_0=\omega_0/2\pi</math>, <math>\Delta
 
f=\Delta \omega/2\pi</math> etc.  When quoting values, we will often write
 
f=\Delta \omega/2\pi</math> etc.  When quoting values, we will often write
explicitly <math>\omega_0=2\pi\times\unit{1}{\mega\hertz}</math> rather than
+
explicitly <math>\omega_0=2\pi\times{{1}\,{{\rm MHz}}}</math> rather than
<math>\omega_0=\unit{6.28\times10^6}{\reciprocal\second}</math> to remind ourselves that
+
<math>\omega_0={{6.28\times10^6}\,{{\rm s}^{-1}}}</math> to remind ourselves that
 
the quantity in question is an angular frequency.  We will never write
 
the quantity in question is an angular frequency.  We will never write
<math>\omega_0=\unit{6.28\times10^6}{Hz}</math>: although formally dimensionally
+
<math>\omega_0={{6.28\times10^6}\,{{\rm Hz}}}</math>: although formally dimensionally
 
consistent, this invites confusion with real (laboratory or Hertzian)
 
consistent, this invites confusion with real (laboratory or Hertzian)
 
frequencies.  For brevity, we will often write or say "frequency" when we mean
 
frequencies.  For brevity, we will often write or say "frequency" when we mean
 
angular frequency, but will quote real frequencies as
 
angular frequency, but will quote real frequencies as
<math>f_0=\unit{1}{\mega\hertz}</math>.  Note that the natural unit for decay rate
+
<math>f_0={{1}\,{{\rm MHz}}}</math>.  Note that the natural unit for decay rate
 
constants is that of an angular frequency, as in <math>e^{-i\omega_0 t-\gamma t}</math>.
 
constants is that of an angular frequency, as in <math>e^{-i\omega_0 t-\gamma t}</math>.
 
Therefore we will express decay rates as inverse times in angular frequency
 
Therefore we will express decay rates as inverse times in angular frequency
units: <math>\gamma=\unit{10^4}{\reciprocal\second}</math> for instance, but not
+
units: <math>\gamma={{10^4}\,{{\rm s}^{-1}}}</math> for instance, but not
<math>\gamma=\unit{10^4}{\hertz}</math>, nor <math>\gamma=2\pi\times\unit{1.6}{\kilo\hertz}</math>.
+
<math>\gamma={{10^4}\,{{\rm Hz}}}</math>, nor <math>\gamma=2\pi\times{{1.6}\,{{\rm kHz}}}</math>.
 
Damping time constants are the inverse of decay rate constants,
 
Damping time constants are the inverse of decay rate constants,
<math>\tau=1/\gamma=\unit{100}{\micro\second}</math>.
+
<math>\tau=1/\gamma={{100}\,{{\mu \rm s}}}</math>.
== Resonance Widths and Uncertainty Relations ==
+
 
 +
=== Resonance Widths and Uncertainty Relations ===
 
From <math>\Delta\omega=\gamma</math> it follows that damping time <math>\tau</math> and the resonance
 
From <math>\Delta\omega=\gamma</math> it follows that damping time <math>\tau</math> and the resonance
linewidth <math>\Delta\omega</math> of the driven system obey: <math>\Delta\omega\tau=1</math> or,
+
linewidth <math>\Delta\omega</math> of the driven system obey: <math>\Delta\omega\cdot\tau=1</math> or,
 
assuming <math>E=\hbar\omega</math>, <math>\Delta E\tau=\hbar</math>: a finite number of frequency
 
assuming <math>E=\hbar\omega</math>, <math>\Delta E\tau=\hbar</math>: a finite number of frequency
 
components or energies (<math>\Delta\omega>0</math>) is necessary to synthesize a pulse of
 
components or energies (<math>\Delta\omega>0</math>) is necessary to synthesize a pulse of
 
finite (<math>\tau<\infty</math>) width in time.
 
finite (<math>\tau<\infty</math>) width in time.
\begin{figure}
+
 
 
<blockquote>
 
<blockquote>
::[[Image:resonances-gated-pulse.png|thumb|400px|none|]]
+
<figure id="fig:gated_pulse">
   \caption{Measurement in a limited time <math>\Delta t</math>, modelled as an ideal
+
[[Image:resonances-gated-pulse.png|thumb|400px|none|]]
 +
<caption>
 +
   Measurement in a limited time <math>\Delta t</math>, modelled as an ideal
 
   monochromatic sine wave of frequency <math>\omega_0 / 2 \pi = 1</math> gated by an
 
   monochromatic sine wave of frequency <math>\omega_0 / 2 \pi = 1</math> gated by an
   observation window of finite width <math>\Delta t</math>}
+
   observation window of finite width <math>\Delta t</math>
 
+
</caption>
 +
</figure>
 
</blockquote>
 
</blockquote>
\end{figure}
+
 
 
This is quite similar to an uncertainty relation familiar from Fourier
 
This is quite similar to an uncertainty relation familiar from Fourier
 
transformation theory, according to which the measurement of a frequency in a
 
transformation theory, according to which the measurement of a frequency in a
finite time <math>\Delta t</math> (see Figure \ref{fig:gated_pulse}) results in a frequency
+
finite time <math>\Delta t</math> (see <xr id="fig:gated_pulse"/>) results in a frequency spread <math>\Delta\omega</math> obeying <math>\Delta \omega \Delta t \geq 1/2</math>.
spread <math>\Delta\omega</math> obeying <math>\Delta \omega \Delta t \geq 1/2</math>.
 
 
By using <math>E=\hbar\omega</math> we can further connect this with the usual Heisenberg
 
By using <math>E=\hbar\omega</math> we can further connect this with the usual Heisenberg
 
uncertainty relation
 
uncertainty relation
Line 164: Line 168:
 
\Delta E \Delta t \geq \hbar / 2
 
\Delta E \Delta t \geq \hbar / 2
 
</math>
 
</math>
\QA{
+
 
Does the Heisenberg uncertainty relation <math>\Delta E\Delta t\geq \hbar/2</math>,
+
'''Question:''' <definition id="q:classical_line_splitting" noautocaption noblock><caption>(Q%i)</caption></definition> Does the Heisenberg uncertainty relation <math>\Delta E\Delta t\geq \hbar/2</math>, or rather the frequency uncertainty relation <math>\Delta \omega\Delta
or rather the frequency uncertainty relation <math>\Delta \omega\Delta
 
 
t\geq 1/2</math> that follows from (classical) Fourier theory hold in classical
 
t\geq 1/2</math> that follows from (classical) Fourier theory hold in classical
 
systems?  Can you measure the angular frequency of a classical harmonic
 
systems?  Can you measure the angular frequency of a classical harmonic
 
oscillator in a time <math>\Delta t</math> with an accuracy better than <math>\Delta
 
oscillator in a time <math>\Delta t</math> with an accuracy better than <math>\Delta
 
\omega=1/2\Delta t</math>?
 
\omega=1/2\Delta t</math>?
}{
+
 
Yes: if you have a good model for the signal, for instance if you know that it
+
'''Answer:''' Yes - if you have a good model for the signal, for instance if you know that it
 
is a pure sine wave, and if the signal to noise ratio (SNR) of the measurement
 
is a pure sine wave, and if the signal to noise ratio (SNR) of the measurement
 
is good enough, then you can fit the sine wave's frequency to much better
 
is good enough, then you can fit the sine wave's frequency to much better
 
accuracy than its spectral width <math>\Delta\omega</math> (see Fig.
 
accuracy than its spectral width <math>\Delta\omega</math> (see Fig.
\ref{fig:line_splitting}).  As a general rule, the line center can be found to
+
<xr id="fig:line_splitting"/>).  As a general rule, the line center can be found to
within an uncertainty <math>\delta\omega\approx\Delta\Omega/\text{SNR}</math>.  This is
+
within an uncertainty <math>\delta\omega\approx\Delta\omega/\text{SNR}</math>.  This is
 
known as splitting the line.  Splitting the line by a factor of 100 is fairly
 
known as splitting the line.  Splitting the line by a factor of 100 is fairly
 
straightforward, splitting it by a factor of a 1000 is a real challenge.  As an
 
straightforward, splitting it by a factor of a 1000 is a real challenge.  As an
 
extreme example of this, Caesium fountain clocks interrogate a
 
extreme example of this, Caesium fountain clocks interrogate a
\unit{9}{\giga\hertz} transition for a typical measurement time of
+
9 GHz transition for a typical measurement time of
\unit{1}{\second}, yielding <math>\Delta\omega/\omega\approx 10^{-10}</math>, but
+
1 s, yielding <math>\Delta\omega/\omega\approx 10^{-10}</math>, but
 
the best ones can nonetheless achieve relative accuracies of <math>10^{-16}</math>
 
the best ones can nonetheless achieve relative accuracies of <math>10^{-16}</math>
\cite{Santarelli1999}.  Of course, this sort of performance requires a very good
+
<ref name="Santarelli1999">G. Santarelli, Ph. Laurent, P. Lemonde, A. Clairon, A. G. Mann, S. Chang, A. N. Luiten, and C. Salomon. Quantum projection noise in an atomic fountain: A high-stability cesium frequency standard. Phys. Rev. Lett., 82:4619, 1999.</ref>.  Of course, this sort of performance requires a very good
 
understanding of the line shape and of systematics.
 
understanding of the line shape and of systematics.
}
+
 
\begin{figure}
+
 
 +
 
 
<blockquote>
 
<blockquote>
::[[Image:resonances-line-splitting.png|thumb|400px|none|]]
+
<figure id="fig:line_splitting">
\caption{Splitting the line in time and frequency domains.  Given a sufficiently
+
[[Image:resonances-line-splitting.png|thumb|500px|none|]]
 +
<caption> Splitting the line in time and frequency domains.  Given a sufficiently
 
good model of the signal or line shape, and adequate signal-to-noise, one can
 
good model of the signal or line shape, and adequate signal-to-noise, one can
 
find the center frequency <math>\omega_0</math> of the underlying signal to much better
 
find the center frequency <math>\omega_0</math> of the underlying signal to much better
than <math>1 \text{ cycle}/\Delta t</math> or the line width.}
+
than <math>1 \text{ cycle}/\Delta t</math> or the line width.
+
</caption>
 +
</figure>
 
</blockquote>
 
</blockquote>
\end{figure}
+
 
\QU{
+
'''Question:''' <definition id="q:quantum_line_splitting" noautocaption noblock><caption>(Q%i)</caption></definition> Can you measure the angular frequency of a quantum mechanical harmonic oscillator in a time <math>\Delta t</math> to better than <math>\Delta \omega=1/2\Delta t</math>?
Can you measure the angular frequency of a quantum mechanical harmonic
+
 
oscillator in a time <math>\Delta t</math> to better than <math>\Delta \omega=1/2\Delta
+
'''Question:''' <definition id="q:laser_line_splitting" noautocaption noblock><caption>(Q%i)</caption></definition> Can you measure the angular frequency of a laser pulse lasting a time <math>\Delta t</math> to better than <math>\Delta \omega=1/2\Delta t</math>?
t</math>?
+
 
}
+
If you answered <xr id="q:quantum_line_splitting"/> and
\QU{
+
<xr id="q:classical_line_splitting"/> differently, you may have a problem with
Can you measure the angular frequency of a laser pulse lasting a time <math>\Delta t</math>
+
<xr id="q:laser_line_splitting"/>. Is a laser pulse quantum or classical?  Clearly it
to better than <math>\Delta \omega=1/2\Delta t</math>?}
 
If you answered \ref{q:quantum_line_splitting} and
 
\ref{q:classical_line_splitting} differently, you may have a problem with
 
\ref{q:laser_line_splitting}. Is a laser pulse quantum or classical?  Clearly it
 
 
is possible to beat <math>\Delta\omega=1/2\Delta t</math> for a laser pulse.  For
 
is possible to beat <math>\Delta\omega=1/2\Delta t</math> for a laser pulse.  For
 
instance, you can superimpose the laser pulse with a laser of fixed and known
 
instance, you can superimpose the laser pulse with a laser of fixed and known
frequency on a photodiode, and fit the observed beatnote.  The stronger the
+
frequency on a photodiode, and fit the observed beat note.  The stronger the
probe pulse, the better the SNR of the beatnote, and the more accurately you can
+
probe pulse, the better the SNR of the beat note, and the more accurately you can
 
extract the probe frequency. So how are we to reconcile quantum mechanics and
 
extract the probe frequency. So how are we to reconcile quantum mechanics and
 
classical mechanics, and what does the Heisenberg uncertainty really state?
 
classical mechanics, and what does the Heisenberg uncertainty really state?
 +
 
The Heisenberg uncertainty relation makes a statement about predicting the
 
The Heisenberg uncertainty relation makes a statement about predicting the
 
outcome of a single measurement on a single system.  For a single photon, the
 
outcome of a single measurement on a single system.  For a single photon, the
Line 222: Line 225:
 
improves with probe pulse strength because we are measuring many photons - for
 
improves with probe pulse strength because we are measuring many photons - for
 
the purposes of this discussion we could have measured the frequencies of the
 
the purposes of this discussion we could have measured the frequencies of the
photons sequentially.  For independent measurement of <math>n</math> uncorrelated photons
+
photons sequentially.   
 +
 
 +
For independent measurement of <math>n</math> uncorrelated photons
 
the SNR is given by <math>\sqrt{n}</math>: the signal grows as <math>n</math>, while the noise is the
 
the SNR is given by <math>\sqrt{n}</math>: the signal grows as <math>n</math>, while the noise is the
 
shot noise of the photon number, which grows as <math>\sqrt{n}</math>.  This SNR allows a
 
shot noise of the photon number, which grows as <math>\sqrt{n}</math>.  This SNR allows a
Line 228: Line 233:
 
quantum limit.  If we allow the use of entangled or correlated states of the
 
quantum limit.  If we allow the use of entangled or correlated states of the
 
photons, then the uncertainty can be as low as the Heisenberg limit
 
photons, then the uncertainty can be as low as the Heisenberg limit
<math>1/2\Delta t n</math> \cite{Wineland1992,Wineland1994}.
+
<math>1/2\Delta t n</math> <ref name="Wineland1992">D. J. Wineland, J. J. Bollinger, W. M. Itano, F. L. Moore, and D. J. Heinzen. Spin squeezing and reduced quantum noise in spectroscopy. Phys. Rev. A, 46(11):R6797–R6800, Dec 1992.</ref><ref name="Wineland1994">D. J. Wineland, J. J. Bollinger, W. M. Itano, and D. J. Heinzen. Squeezed atomic states and projection noise in spectroscopy. Phys. Rev. A, 50(1):67–88, Jul 1994.</ref>.
Let us now revisit \ref{q:quantum_line_splitting}.  You may have heard that the
+
 
 +
Let us now revisit <xr id="q:quantum_line_splitting"/>.  You may have heard that the
 
quantum mechanical description of electromagnetism, quantum electrodynamics
 
quantum mechanical description of electromagnetism, quantum electrodynamics
 
(QED), represents any single mode of the electromagnetic field by a harmonic
 
(QED), represents any single mode of the electromagnetic field by a harmonic
Line 236: Line 242:
 
This description is valid because photons to a very good approximation do not
 
This description is valid because photons to a very good approximation do not
 
interact: the addition of a photon changes the system's energy always by the
 
interact: the addition of a photon changes the system's energy always by the
same increment.  Since the many-photon pulse from \ref{q:laser_line_splitting}
+
same increment.  Since the many-photon pulse from <xr id="q:laser_line_splitting"/>
 
maps onto a quantum harmonic oscillator, it seems to follow that
 
maps onto a quantum harmonic oscillator, it seems to follow that
\ref{q:quantum_line_splitting} must also be answered in the affirmative.  On the
+
<xr id="q:quantum_line_splitting"/> must also be answered in the affirmative.   
other hand, a harmonic oscillator is a single quantum system to which the
+
 
 +
On the other hand, a harmonic oscillator is a single quantum system to which the
 
Heisenberg limit must apply.  The resolution of this apparent contradiction is
 
Heisenberg limit must apply.  The resolution of this apparent contradiction is
that \ref{q:quantum_line_splitting} is asking about a measurement of the
+
that <xr id="q:quantum_line_splitting"/> is asking about a measurement of the
 
fundamental frequency of the harmonic oscillator, not the energy of a particular
 
fundamental frequency of the harmonic oscillator, not the energy of a particular
 
level.  Therefore if you measure the energy of the n-th level to <math>\Delta
 
level.  Therefore if you measure the energy of the n-th level to <math>\Delta
Line 247: Line 254:
 
the ground state through a nonlinear process, then the uncertainty on the
 
the ground state through a nonlinear process, then the uncertainty on the
 
harmonic oscillator resonance frequency (that corresponds to the laser frequency
 
harmonic oscillator resonance frequency (that corresponds to the laser frequency
in \ref{q:quantum_line_splitting}) is given by <math>\Delta \omega_0=\Delta
+
in <xr id="q:quantum_line_splitting"/>) is given by <math>\Delta \omega_0=\Delta
E/n=1/n2\Delta t</math>. �If the interaction with the oscillator is
+
E/n=1/n2\Delta t</math>.  
restricted to classical fields or forces, then there is an additional
+
 
 +
If the interaction with the oscillator is restricted to classical fields or forces, then there is an additional
 
uncertainty of <math>\sqrt{n}</math> on which particular level of the oscillator is being
 
uncertainty of <math>\sqrt{n}</math> on which particular level of the oscillator is being
 
measured and so we recover the standard quantum limit <math>1/2\Delta t\sqrt{n}</math>
 
measured and so we recover the standard quantum limit <math>1/2\Delta t\sqrt{n}</math>
 
mentioned previously.
 
mentioned previously.
== Resonances and Two-Level Systems ==
+
 
 +
== Magnetic Resonance: The Classical Magnetic Moment in a Spatially Uniform Field ==
 +
 
 +
=== Harmonic oscillator versus two-level systems ===
 +
 
 
Now, unlike in classical mechanics, most resonances studied in atomic physics
 
Now, unlike in classical mechanics, most resonances studied in atomic physics
 
are not harmonic oscillators, but two-level systems.  Unlike harmonic
 
are not harmonic oscillators, but two-level systems.  Unlike harmonic
Line 260: Line 272:
 
oscillator amplitude can become arbitrarily large.  In contrast, the amplitude
 
oscillator amplitude can become arbitrarily large.  In contrast, the amplitude
 
of oscillation in a two-level system is limited to one half in the appropriate
 
of oscillation in a two-level system is limited to one half in the appropriate
dimensionless units.\footnote{An analogous dimensionless amplitude for the
+
dimensionless units.(An analogous dimensionless amplitude for the
 
harmonic oscillator would be the amplitude measured in units of the oscillator
 
harmonic oscillator would be the amplitude measured in units of the oscillator
ground state size.}
+
ground state size.)
 +
 
 
Why, and under what conditions, do classical harmonic oscillator models of a
 
Why, and under what conditions, do classical harmonic oscillator models of a
 
two-level system work? A two-level system of energy difference <math>E</math> can be
 
two-level system work? A two-level system of energy difference <math>E</math> can be
Line 273: Line 286:
 
many linear atomic properties (for instance the refractive index) very well.
 
many linear atomic properties (for instance the refractive index) very well.
 
See "The origin of the refractive index" in chapter 31 of the Feynman
 
See "The origin of the refractive index" in chapter 31 of the Feynman
Lectures on Physics \cite{Feynman1963}.
+
Lectures on Physics <ref name="Feynman1963">Richard Feynman, Robert B. Leighton, and Matthew L. Sands. The Feynman Lectures on Physics. Addison-Wesley, 1963. 3 volumes.</ref>.
 +
 
 
When saturation comes into play, i.e. when the initial ground state is
 
When saturation comes into play, i.e. when the initial ground state is
 
appreciably depleted, the harmonic oscillator ceases to be a good model.  The
 
appreciably depleted, the harmonic oscillator ceases to be a good model.  The
Line 281: Line 295:
 
the motion of a classical magnetic moment in a uniform field provides a model
 
the motion of a classical magnetic moment in a uniform field provides a model
 
that captures almost all features of the quantum-mechanical two-level system,
 
that captures almost all features of the quantum-mechanical two-level system,
the exception beting the projection onto one of the two possible outcomes in a
+
the exception being the projection onto one of the two possible outcomes in a measurement.
measurement.
+
 
\section{Magnetic Resonance: The Classical Magnetic Moment in a Spatially
 
Uniform Field}
 
 
=== Magnetic Moment in a Static Field ===
 
=== Magnetic Moment in a Static Field ===
 
The interaction energy of a magnetic moment <math> {\bf{\mu}} </math> with a magnetic field
 
The interaction energy of a magnetic moment <math> {\bf{\mu}} </math> with a magnetic field
Line 300: Line 312:
 
</math>
 
</math>
 
does not.  For an angular momentum <math> {\bf{L}} </math> the equation of motion is then
 
does not.  For an angular momentum <math> {\bf{L}} </math> the equation of motion is then
:<math>
+
<equation id="eq:classical_precession_in_static_field" noautocaption>
 +
<span style="float:right; display:block;"><caption>(%i)</caption></span>
 +
<math>
 
   \dot{ {\bf{L}} }
 
   \dot{ {\bf{L}} }
 
   = {\bf{T}}  
 
   = {\bf{T}}  
Line 307: Line 321:
 
    
 
    
 
</math>
 
</math>
 +
</equation>
 
where we have introduced the gyromagnetic ratio <math>\gamma</math> as the proportionality
 
where we have introduced the gyromagnetic ratio <math>\gamma</math> as the proportionality
 
constant between angular momentum and magnetic moment, as shown in Figure
 
constant between angular momentum and magnetic moment, as shown in Figure
\ref{fig:static_precession}.
+
<xr id="fig:static_precession"/>.
\begin{figure}
+
 
 
<blockquote>
 
<blockquote>
::[[Image:resonances-static-precession.png|thumb|400px|none|]]
+
<figure id="fig:static_precession">
\caption{Precession of a the magnetic moment and associated angular momentum
+
 
about a static field <math> {\bf{B}} </math>.}
+
[[Image:resonances-static-precession.png|thumb|400px|none|]]
 +
<caption>
 +
Precession of a the magnetic moment and associated angular momentum
 +
about a static field <math> {\bf{B}} </math>.
 
   
 
   
 +
</caption>
 +
</figure>
 
</blockquote>
 
</blockquote>
\end{figure}
+
 
 
This describes the precession of the magnetic moment about the magnetic field
 
This describes the precession of the magnetic moment about the magnetic field
 
with angular frequency
 
with angular frequency
Line 324: Line 344:
 
</math>
 
</math>
 
<math>\Omega_L</math> is known as the Larmor frequency.
 
<math>\Omega_L</math> is known as the Larmor frequency.
For electrons we have <math>\gamma_e=2\pi\times\unit{2.8}{\mega\hertz\per G}</math>,
+
For electrons we have <math>\gamma_e=2\pi\times{{2.8}\,{{\rm MHz/G}}}</math>,
for protons <math>\gamma_e=2\pi\times\unit{4.2}{\kilo\hertz\per G}</math>.
+
for protons <math>\gamma_p=2\pi\times{{4.2}\,{{\rm KHz/G}}}</math>.
=== An Alternative Solution: Rotating Coordinate System ===
+
 
 +
=== Transformation to a Rotating Coordinate System ===
 
A vector <math> {\bf{A}} </math> rotating at constant angular velocity <math> {\bf{\Omega}} </math> is
 
A vector <math> {\bf{A}} </math> rotating at constant angular velocity <math> {\bf{\Omega}} </math> is
 
described by
 
described by
Line 336: Line 357:
 
:<math>
 
:<math>
 
\dot{ {\bf{A}} }_\text{in} =
 
\dot{ {\bf{A}} }_\text{in} =
\dot{ {\bf{A}} }_\text{rot}+ {\bf{\Omega}} \times {\bf{A}} _\text{in}
+
\dot{ {\bf{A}} }_\text{rot} + {\bf{\Omega}} \times {\bf{A}} _\text{in}
 
</math>
 
</math>
 
This follows immediately from the following facts:
 
This follows immediately from the following facts:
\begin{itemize}
+
 
* If <math> {\bf{A}} </math> is constant in the rotating system then
+
* If <math> {\bf{A}} </math> is constant in the rotating system then <math>\dot{ {\bf{A}} }_\text{in}= {\bf{\Omega}} \times {\bf{A}} _\text{in}</math>.
<math>\dot{ {\bf{A}} }_\text{in}= {\bf{\Omega}} \times {\bf{A}} _\text{in}</math>.
+
* If <math> {\bf{\Omega}} =0</math> then <math>\dot{ {\bf{A}} }_\text{in}=\dot{ {\bf{A}} }_\text{rot}</math>.
* If <math> {\bf{\Omega}} =0</math> then
+
* Coordinate rotation is a linear transformation.
<math>\dot{ {\bf{A}} }_\text{in}=\dot{ {\bf{A}} }_\text{rot}</math>.
+
 
* Coordinate rotation is a linear transformation.
 
\end{itemize}
 
 
This transformation is sometimes abbreviated as the schematic rule
 
This transformation is sometimes abbreviated as the schematic rule
:<math>
+
<equation id="eq:rot_frame_transformation" noautocaption>
 +
<span style="float:right; display:block;"><caption>(%i)</caption></span>
 +
<math>
 
   \left(\frac{d}{dt}\right)_\text{rot}=
 
   \left(\frac{d}{dt}\right)_\text{rot}=
 
   \left(\frac{d}{dt}\right)_\text{in}- {\bf{\Omega}} \times\big(\big)_\text{in}
 
   \left(\frac{d}{dt}\right)_\text{in}- {\bf{\Omega}} \times\big(\big)_\text{in}
 
+
 
</math>
 
</math>
 +
</equation>
 
It follows that the angular momentum
 
It follows that the angular momentum
 
in a rotating frame obeys
 
in a rotating frame obeys
Line 363: Line 385:
 
think of a fictitious magnetic field <math> {\bf{B}} _\text{fict}= {\bf{\Omega}} /\gamma</math>
 
think of a fictitious magnetic field <math> {\bf{B}} _\text{fict}= {\bf{\Omega}} /\gamma</math>
 
that appears in a rotating frame.
 
that appears in a rotating frame.
 +
 
=== Larmor's Theorem for a Charged Particle in a Magnetic Field ===
 
=== Larmor's Theorem for a Charged Particle in a Magnetic Field ===
 
The vanishing of the torque on a magnetic moment when viewed in the correct
 
The vanishing of the torque on a magnetic moment when viewed in the correct
rotating frame is reminiscent of Larmor's theorm for the motion of a charged
+
rotating frame is reminiscent of Larmor's theorem for the motion of a charged
 
particle in a magnetic field, which we now present.
 
particle in a magnetic field, which we now present.
 +
 +
According to answers.com, Lamor's theorem can be stated as
 +
 +
For a system of charged particles, all having the same ratio of charge to mass, moving in a central field of force, the motion in a uniform magnetic induction B is, to first order in B, the same as a possible motion in the absence of B except for the superposition of a common precession of angular frequency equal to the Larmor frequency.
 +
 +
This is also nicely discussed in the Feynman Lectures of Physics Vol. 2, 34-5 (https://www.feynmanlectures.caltech.edu/II_34.html).
 +
 
If the Lorentz force acts in an inertial frame,
 
If the Lorentz force acts in an inertial frame,
 
:<math>
 
:<math>
Line 372: Line 402:
 
</math>
 
</math>
 
then in the rotating frame, according to the rule
 
then in the rotating frame, according to the rule
\ref{eqn:rot_frame_transformation} we have
+
<xr id="eq:rot_frame_transformation"/> we have
\begin{align*}
+
:<math>\begin{align}  
   \dot{ <math>{\bf{r}}</math> }_\text{rot}
+
   \dot{ {\bf{r}} }_\text{rot}
   &= \dot{ <math>{\bf{r}}</math> }_\text{in} -   <math>{\bf{\Omega}}</math> \times   <math>{\bf{r}}</math> _\text{in} \\
+
   &= \dot{ {\bf{r}} }_\text{in} - {\bf{\Omega}}  \times {\bf{r}} _\text{in} \\
   \ddot{ <math>{\bf{r}}</math> }_\text{rot}
+
   \ddot{ {\bf{r}} }_\text{rot}
   &= \ddot{ <math>{\bf{r}}</math> }_\text{in} - 2   <math>{\bf{\Omega}}</math> \times \dot{ <math>{\bf{r}}</math> }_\text{in}
+
   &= \ddot{ {\bf{r}} }_\text{in} - 2 {\bf{\Omega}}  \times \dot{ {\bf{r}} }_\text{in}
     +   <math>{\bf{\Omega}}</math> \times \left(   <math>{\bf{\Omega}}</math> \times   <math>{\bf{r}}</math> _\text{in}
+
     + {\bf{\Omega}}  \times \left( {\bf{\Omega}}  \times {\bf{r}} _\text{in}
 
     \right)
 
     \right)
\end{align*}
+
\end{align}</math>
 
resulting in a force <math> {\bf{F}} _\text{rot}=m\ddot{ {\bf{r}} }_\text{rot}</math> in the rotating frame given by
 
resulting in a force <math> {\bf{F}} _\text{rot}=m\ddot{ {\bf{r}} }_\text{rot}</math> in the rotating frame given by
\begin{align*}
+
:<math>\begin{align}  
    <math>{\bf{F}}</math> _\text{rot}
+
  {\bf{F}} _\text{rot}
   &= q   <math>{\bf{v}}</math> _\text{in} \times   <math>{\bf{B}}</math> - 2 m   <math>{\bf{\Omega}}</math> \times
+
   &= q {\bf{v}} _\text{in} \times {\bf{B}}  - 2 m {\bf{\Omega}}  \times
      <math>{\bf{v}}</math> _\text{in} + m   <math>{\bf{\Omega}}</math> \times \left(   <math>{\bf{\Omega}}</math> \times
+
    {\bf{v}} _\text{in} + m {\bf{\Omega}}  \times \left( {\bf{\Omega}}  \times
      <math>{\bf{r}}</math> _\text{in} \right) \\
+
    {\bf{r}} _\text{in} \right) \\
   &= q   <math>{\bf{v}}</math> _\text{in} \times \left(   <math>{\bf{B}}</math> + 2 \frac{m}{q}   <math>{\bf{\Omega}}</math>
+
   &= q {\bf{v}} _\text{in} \times \left( {\bf{B}}  + 2 \frac{m}{q} {\bf{\Omega}}  
     \right) + m   <math>{\bf{\Omega}}</math> \times \left(   <math>{\bf{\Omega}}</math> \times
+
     \right) + m {\bf{\Omega}}  \times \left( {\bf{\Omega}}  \times
      <math>{\bf{r}}</math> _\text{in} \right)
+
    {\bf{r}} _\text{in} \right)
\end{align*}
+
\end{align}</math>
 
where we have used
 
where we have used
 
<math>m\ddot{r}_\text{in}= {\bf{F}} _\text{in}=q {\bf{v}} _\text{in}\times {\bf{B}} </math>.
 
<math>m\ddot{r}_\text{in}= {\bf{F}} _\text{in}=q {\bf{v}} _\text{in}\times {\bf{B}} </math>.
Line 400: Line 430:
 
:<math>
 
:<math>
 
  {\bf{F}} _\text{rot}
 
  {\bf{F}} _\text{rot}
=\frac{q^2}{4m}B^2 {\bf{\hat e}} _z\times\left(\vctr{\hat
+
=\frac{q^2}{4m}B^2 {\bf{\hat e}} _z\times\left( {\bf{\hat e}} _z\times {\bf{r}} _\text{in}\right)\approx 0
e}_z\times {\bf{r}} _\text{in}\right)\approx 0
 
 
</math>
 
</math>
 
if the <math>B</math> field is not too large.  Thus the Lorentz force approximately
 
if the <math>B</math> field is not too large.  Thus the Lorentz force approximately
disappears in the rotating frame. Note that while the vanishing of the force is
+
disappears in the rotating frame.
approximate, the vanishing of the torque on a magnetic moment in the rotating
+
 
frame is an exact result.
+
Although Larmor's theorem is suggestive of the rotating co-ordinate transformation,
 +
it is important to realize that the two transformations, though identical in form,
 +
apply to fundamentally different systems. A magnetic moment is not necessarily charged-
 +
for example a neutral atom can have a net magnetic moment, and the neutron possesses a
 +
magnetic moment in spite of being neutral - and it experiences no net force in a uniform
 +
magnetic field. Furthermore, the rotating co-ordinate transformation is exact for a magnetic moment, whereas Larmor's theorem for the motion of a charged particle is only valid when the <math> B^2 </math> term is neglected.
 +
 
 +
Note:  A breakdown of Larmor's theorem occurs for free electrons.  Free electrons orbit in a magnetic field at the cyclotron frequency <math>\omega_c=qB/m</math> which is ''twice'' Larmor's frequency.  The reason is that the orbiting velocity is now given by <math>v=\omega_c r </math>.  As can be seen in the equation above, in this case, the centrifugal force equals minus one half of the Coriolis force, and therefore twice the frequency of the rotating frame is needed to cancel the effects of the applied magnetic field.
 +
 
 +
The reason why Larmor's theorem breaks down for free electrons is that the total velocity of the electron IS the rotational cyclotron motion.  In contrast, in a composite system of positive and negative charges, you have Coulomb forces and orbital motion with high velocities, much higher than those due to the rotational motion.
 +
 
 
=== Rotating Magnetic Field on Resonance ===
 
=== Rotating Magnetic Field on Resonance ===
\begin{figure}
+
 
 
<blockquote>
 
<blockquote>
::[[Image:resonances-rotating-frame.png|thumb|400px|none|]]
+
<figure id="fig:rotating_frame">
\caption{Field and moment vectors in the static and rotating frames for the case
+
[[Image:resonances-rotating-frame.png|thumb|400px|none|]]
of resonant drive.}
+
<caption>Field and moment vectors in the static and rotating frames for the case
 +
of resonant drive.</caption>
 +
</figure>
 
   
 
   
 
</blockquote>
 
</blockquote>
\end{figure}
+
 
 
Consider a magnetic moment <math> {\bf{\mu}} </math> precessing about a field
 
Consider a magnetic moment <math> {\bf{\mu}} </math> precessing about a field
 
<math> {\bf{B}} =B_0 {\bf{\hat e}} _z</math> with <math> {\bf{\mu}} =(\mu, \theta, \phi=-\omega_0 t)</math>
 
<math> {\bf{B}} =B_0 {\bf{\hat e}} _z</math> with <math> {\bf{\mu}} =(\mu, \theta, \phi=-\omega_0 t)</math>
in spherical coordinates, where <math>\omega_0=-\gamma B_0</math>.  Assume that we now
+
in spherical coordinates, where <math>\omega_0=-\gamma B_0</math> (as shown in fig:rotating_frame/>).  Assume that we now
 
apply an additional field <math> {\bf{B}} _1</math>, in the <math>xy</math>-plane rotating at
 
apply an additional field <math> {\bf{B}} _1</math>, in the <math>xy</math>-plane rotating at
 
<math>\omega_0</math>.  To solve the resulting problem it is simplest to go into the
 
<math>\omega_0</math>.  To solve the resulting problem it is simplest to go into the
rotating frame (Figure \ref{fig:rotating_frame}).  Then <math> {\bf{B}} _1</math> is
+
rotating frame (fig:rotating_frame/>).  Then <math> {\bf{B}} _1</math> is
 
stationary, say along <math> {\bf{\hat e}} _x</math>, and there is an additional fictitious
 
stationary, say along <math> {\bf{\hat e}} _x</math>, and there is an additional fictitious
 
field <math> {\bf{B}} _\text{fict}= {\bf{\omega_0}} /\gamma=- {\bf{B}} _0</math> which
 
field <math> {\bf{B}} _\text{fict}= {\bf{\omega_0}} /\gamma=- {\bf{B}} _0</math> which
Line 432: Line 473:
 
A magnetic moment initially along the <math>- {\bf{\hat e}} _z</math> axis will point along
 
A magnetic moment initially along the <math>- {\bf{\hat e}} _z</math> axis will point along
 
the <math>+ {\bf{\hat e}} _z</math> axis at a time <math>T</math> given by <math>\omega_r T=\pi</math>, while a
 
the <math>+ {\bf{\hat e}} _z</math> axis at a time <math>T</math> given by <math>\omega_r T=\pi</math>, while a
magnetic moment parallel or antiparallel to applied magnetic field <math> {\bf{B}} _1</math>
+
magnetic moment parallel or antiparallel to the applied magnetic field <math> {\bf{B}} _1</math>
 
does not precess in the rotating frame.
 
does not precess in the rotating frame.
\QU{
+
 
Assume the magnetic moment is initially pointing
+
'''Question:''' <definition id="q:rabi_freq_blue_detuned" noautocaption noblock><caption>(Q%i)</caption></definition> Assume the magnetic moment is initially pointing
 
along the <math>- {\bf{\hat e}} _z</math> axis.  Assume that a rotating field <math>B_1\ll B_0</math> is
 
along the <math>- {\bf{\hat e}} _z</math> axis.  Assume that a rotating field <math>B_1\ll B_0</math> is
 
applied, but that it rotates at a frequency <math>\omega_1>\omega_0</math>,
 
applied, but that it rotates at a frequency <math>\omega_1>\omega_0</math>,
Line 441: Line 482:
 
Compared to the on-resonant case, <math>\omega_1=\omega_0</math>, is the oscillation frequency of
 
Compared to the on-resonant case, <math>\omega_1=\omega_0</math>, is the oscillation frequency of
 
the magnetic moment.
 
the magnetic moment.
\begin{enumerate}
+
* larger
* larger
+
* the same
* the same
+
* smaller
* smaller
+
 
\end{enumerate}
+
'''Question:''' Same question as <xr id="q:rabi_freq_blue_detuned"/> but for <math>\omega_1<\omega_0</math>.
}
+
 
\QU{
 
Same question as \ref{q:rabi_freq_blue_detuned} but for <math>\omega_1<\omega_0</math>.
 
}
 
 
=== Rotating Magnetic Field Off-Resonance ===
 
=== Rotating Magnetic Field Off-Resonance ===
 
If the rotation frequency
 
If the rotation frequency
Line 480: Line 518:
 
<math>\delta=\omega-\omega_0</math> is the detuning from resonance with the Larmor
 
<math>\delta=\omega-\omega_0</math> is the detuning from resonance with the Larmor
 
frequency <math>\omega_0=\gamma B_0</math>.
 
frequency <math>\omega_0=\gamma B_0</math>.
\subsection{Geometrical Solution for the Classical Magnetic Moment in Static and
+
 
Rotating Fields}
+
==== Geometrical Solution for the Classical Magnetic Moment in Static and Rotating Fields ====
\begin{figure}
+
 
 
<blockquote>
 
<blockquote>
::[[Image:resonances-classical-rabi-construction.png|thumb|400px|none|]]
+
<figure id="fig:rotating_coord_construction">
  \caption{Geometrical relations for the spin in combined static and rotating
+
 
  magnetic fields, viewed in the frame co-rotating with the drive field
+
[[Image:resonances-classical-rabi-construction.png|thumb|600px|none|]]
  <math> {\bf{B}} _1</math>.  At lower right is a view looking straight down the
+
<caption> Geometrical relations for the spin in combined static and rotating
  <math> {\bf{B}} _\text{eff}</math> axis.}
+
magnetic fields, viewed in the frame co-rotating with the drive field
 +
<math> {\bf{B}} _1</math>.  At lower right is a view looking straight down the
 +
<math> {\bf{B}} _\text{eff}</math> axis.
 
    
 
    
 +
</caption>
 +
</figure>
 
</blockquote>
 
</blockquote>
\end{figure}
+
 
Referring to Figure \ref{fig:rotating_coord_construction}, we have
+
Referring to <xr id="fig:rotating_coord_construction"/>, we have
\begin{align*}
+
:<math>\begin{align}  
 
   \phi
 
   \phi
 
   &= \Omega_R t \\
 
   &= \Omega_R t \\
Line 504: Line 546:
 
   \Rightarrow \cos \alpha
 
   \Rightarrow \cos \alpha
 
   &= 1 - \frac{A^2}{2 \mu^2}
 
   &= 1 - \frac{A^2}{2 \mu^2}
\end{align*}
+
\end{align}</math>
 
On the other hand
 
On the other hand
\begin{align*}
+
:<math>\begin{align}  
 
   \frac{A}{2}
 
   \frac{A}{2}
 
   &= \mu \sin \theta \sin \frac{\phi}{2} \\
 
   &= \mu \sin \theta \sin \frac{\phi}{2} \\
 
   A
 
   A
 
   &= 2 \mu \sin \theta \sin \frac{\Omega_R t}{2}
 
   &= 2 \mu \sin \theta \sin \frac{\Omega_R t}{2}
\end{align*}
+
\end{align}</math>
 
so that
 
so that
\begin{align}
+
<equation id="eq:classical_rabi_flopping" noautocaption>
 +
<span style="float:right; display:block;"><caption>(%i)</caption></span>
 +
<math>\begin{align}  
 
   \cos \alpha
 
   \cos \alpha
 
   &= 1 - \frac{4 \mu^2 \sin^2 \theta \sin^2 \frac{\Omega_R t}{2}}{2 \mu^2}
 
   &= 1 - \frac{4 \mu^2 \sin^2 \theta \sin^2 \frac{\Omega_R t}{2}}{2 \mu^2}
    \notag \\
+
      \\
   &= 1 - 2 \sin^2 \theta \sin^2 \frac{\Omega_R t}{2} \notag \\
+
   &= 1 - 2 \sin^2 \theta \sin^2 \frac{\Omega_R t}{2}   \\
 
   \mu_z(t)
 
   \mu_z(t)
   &= \mu \cos \alpha \notag \\
+
   &= \mu \cos \alpha   \\
 
   &= \mu \left( 1 - 2 \frac{\omega_R^2}{\delta^2 + \omega_R^2} \sin^2
 
   &= \mu \left( 1 - 2 \frac{\omega_R^2}{\delta^2 + \omega_R^2} \sin^2
     \frac{\Omega_R t}{2} \right) \notag \\
+
     \frac{\Omega_R t}{2} \right)   \\
 
   \mu_z(t)
 
   \mu_z(t)
 
   &= \mu \left( 1 - 2 \frac{\omega_R^2}{\Omega_R^2} \sin^2 \frac{\Omega_R t}{2}
 
   &= \mu \left( 1 - 2 \frac{\omega_R^2}{\Omega_R^2} \sin^2 \frac{\Omega_R t}{2}
 
     \right)
 
     \right)
 
    
 
    
\end{align}
+
\end{align}</math>
 +
</equation>
 
With <math>\omega_0 = \gamma B_0</math> the Larmor frequency of the static field,
 
With <math>\omega_0 = \gamma B_0</math> the Larmor frequency of the static field,
 
<math>\delta=\omega-\omega_0</math> the detuning, <math>\omega_R=\gamma B_1</math> the resonant and
 
<math>\delta=\omega-\omega_0</math> the detuning, <math>\omega_R=\gamma B_1</math> the resonant and
Line 533: Line 578:
 
field than for the resonant case.  The above result is also the correct
 
field than for the resonant case.  The above result is also the correct
 
quantum-mechanical result.
 
quantum-mechanical result.
=== "Rapid" Adiabiatic Passage ===
+
 
 +
If we define the quantity <math> P= \frac{\mu_z(t)-\mu_z(0)}{2\mu_z(0)} </math>, we obtain
 +
 
 +
<math> P= \frac{\omega_R^2}{\Omega_R^2} \sin^2 \frac{\Omega_R t}{2}  </math>
 +
 
 +
In the quantum mechanical treatment (see below), <math> P </math> is the probability to find the system in the second state, or the spin flip probability.
 +
 
 +
=== "Rapid" Adiabiatic Passage (Classical Treatment) ===
 
Rapid adiabatic passage is a technique for inverting a spin by (slowly) sweeping
 
Rapid adiabatic passage is a technique for inverting a spin by (slowly) sweeping
 
the detuning of a drive field through resonance.  "Slowly" means slowly
 
the detuning of a drive field through resonance.  "Slowly" means slowly
 
compared to the Larmor frequency <math>\gamma B_\text{eff}</math> about the effective
 
compared to the Larmor frequency <math>\gamma B_\text{eff}</math> about the effective
static field in the rotating frame for all times. The physical picture is as
+
static field in the rotating frame for all times ("Rapid" means fast compared to relaxation processes which we neglect here).
follows.  Assume the detuning is initially negative (<math>\delta<0</math>,
+
 
<math>\abs\delta\gg\omega_R</math>).  Since
+
The physical picture is as follows.  Assume the detuning is initially negative (<math>\delta<0</math>,
 +
<math> \left| \delta\gg\omega_R\right| </math>).  Since
 
:<math>
 
:<math>
 
\tan\theta=\frac{B_1}{B_0-\frac{\omega}{\gamma}}=\frac{\omega_R}{\omega_0-\omega}=-\frac{\omega_R}{\delta}
 
\tan\theta=\frac{B_1}{B_0-\frac{\omega}{\gamma}}=\frac{\omega_R}{\omega_0-\omega}=-\frac{\omega_R}{\delta}
Line 548: Line 601:
 
precess tightly around <math> {\bf{B}} _\text{eff}</math>, which for <math>\delta=0</math> points
 
precess tightly around <math> {\bf{B}} _\text{eff}</math>, which for <math>\delta=0</math> points
 
along the x axis, and for <math>\delta\gg\omega_R</math> along the <math>- {\bf{\hat e}} _z</math> axis
 
along the x axis, and for <math>\delta\gg\omega_R</math> along the <math>- {\bf{\hat e}} _z</math> axis
(see Figure \ref{fig:rapid_adiabatic_passage}).
+
(see <xr id="fig:rapid_adiabatic_passage"/>).
\begin{figure}
+
 
 
<blockquote>
 
<blockquote>
::[[Image:resonances-adiab.png|thumb|400px|none|]]
+
<figure id="fig:rapid_adiabatic_passage">
\caption{Motion of the spin during rapid adiabatic passage, viewed in the frame
+
[[Image:resonances-adiab.png|thumb|400px|none|]]
 +
<caption> {Motion of the spin during rapid adiabatic passage, viewed in the frame
 
rotating with <math> {\bf{B}} _1</math>.  The spin's rapid precession locks it to the
 
rotating with <math> {\bf{B}} _1</math>.  The spin's rapid precession locks it to the
 
direction of <math> {\bf{B}} _\text{eff}</math> and thus it is dragged through an angle <math>\pi</math>
 
direction of <math> {\bf{B}} _\text{eff}</math> and thus it is dragged through an angle <math>\pi</math>
as the frequency is swept through resonance.}
+
as the frequency is swept through resonance.
+
</caption>
 +
</figure>
 
</blockquote>
 
</blockquote>
\end{figure}
+
 
 
Thus the magnetic moment, starting out along <math> {\bf{B}} _0=B_0 {\bf{\hat e}} _z</math>,
 
Thus the magnetic moment, starting out along <math> {\bf{B}} _0=B_0 {\bf{\hat e}} _z</math>,
 
ends up pointing along <math>- {\bf{B}} _0=B_0 {\bf{\hat e}} _z</math>.  Note that in the
 
ends up pointing along <math>- {\bf{B}} _0=B_0 {\bf{\hat e}} _z</math>.  Note that in the
rotating frame <math>\vctr\mu</math> remains always (almost) parallel to the
+
rotating frame <math> {\bf{\mu}} </math> remains always (almost) parallel to the
 
effective field <math> {\bf{B}} _\text{eff}</math>.
 
effective field <math> {\bf{B}} _\text{eff}</math>.
 
A similar precess is used in magnetic traps for atoms, but there
 
A similar precess is used in magnetic traps for atoms, but there
Line 571: Line 626:
 
smallest and equal to the resonant Rabi frequency <math>\omega_R</math> at <math>\delta=0</math>, the
 
smallest and equal to the resonant Rabi frequency <math>\omega_R</math> at <math>\delta=0</math>, the
 
adiabatic requirement is most severe there, i.e. near <math>\theta=\pi/2</math>.
 
adiabatic requirement is most severe there, i.e. near <math>\theta=\pi/2</math>.
Near <math>\theta=\pi/2</math> we have, with <math>B_z=B_0-1/\gamma\omega(t)</math>,
+
Near <math>\theta=\pi/2</math> we have, with <math>B_z=B_0-\omega(t)/\gamma</math>,
 
:<math>
 
:<math>
 
  \left| \dot\theta\right| =\frac{ \left| \dot{B}_z\right| }{B_1}=\frac{ \left| \dot\omega\right| }{\gamma B_1}
 
  \left| \dot\theta\right| =\frac{ \left| \dot{B}_z\right| }{B_1}=\frac{ \left| \dot\omega\right| }{\gamma B_1}
Line 582: Line 637:
 
<math>\omega</math> per Rabi period <math>T=2\pi/\omega_R</math>,
 
<math>\omega</math> per Rabi period <math>T=2\pi/\omega_R</math>,
 
<math> \left| \Delta\omega\right| = \left| \dot\omega\right| T= \left| \dot\omega\right| /\omega_R 2\pi</math>,
 
<math> \left| \Delta\omega\right| = \left| \dot\omega\right| T= \left| \dot\omega\right| /\omega_R 2\pi</math>,
must be small compared to the Rabi frequency <math>\omega_R</math>. The quantum mechanical
+
must be small compared to the Rabi frequency <math>\omega_R</math>.
treatment yields a probability for non-adiabatic transition (probability for the
+
 
magnetic moment not following the magnetic field) given by
+
Note that the inversion of the spin is independent of whether <math>\omega</math> is swept up or down through the resonance.
:<math>
+
 
P_\text{na}=exp\left(-\frac{\pi}{2}\frac{\omega^2_R}{ \left| \dot\omega\right| }\right)
 
</math>
 
in agreement with the above qualitative discussion.
 
 
== Quantized Spin in a Magnetic Field ==
 
== Quantized Spin in a Magnetic Field ==
 +
 
=== Equation of Motion for the Expectation Value ===
 
=== Equation of Motion for the Expectation Value ===
 
For the system we have been considering, the Hamiltonian is
 
For the system we have been considering, the Hamiltonian is
Line 614: Line 667:
 
Using <math>\left[\hat{L}_k,\hat{L}_l\right]=i\hbar\epsilon_{klm}\hat{L}_m</math> with the
 
Using <math>\left[\hat{L}_k,\hat{L}_l\right]=i\hbar\epsilon_{klm}\hat{L}_m</math> with the
 
Levi-Civita symbol <math>\epsilon_{klm}</math>, we have
 
Levi-Civita symbol <math>\epsilon_{klm}</math>, we have
\begin{align*}
+
:<math>\begin{align}  
 
   \frac{d}{dt} \hat{\mu}_x
 
   \frac{d}{dt} \hat{\mu}_x
 
   &= - \frac{i \gamma^2}{\hbar} B_0 i \hbar \hat{L}_y
 
   &= - \frac{i \gamma^2}{\hbar} B_0 i \hbar \hat{L}_y
Line 623: Line 676:
 
   \frac{d}{dt} \hat{\mu}_z
 
   \frac{d}{dt} \hat{\mu}_z
 
   &= 0
 
   &= 0
\end{align*}
+
\end{align}</math>
 
or in short
 
or in short
\begin{align}
+
:<math>\begin{align}  
   \frac{d}{dt}   <math>{\bf{\hat\mu}}</math>
+
   \frac{d}{dt} {\bf{\hat\mu}}  
   &= \gamma   <math>{\bf{\hat\mu}}</math> \times   <math>{\bf{B}}</math> \\
+
   &= \gamma {\bf{\hat\mu}}  \times {\bf{B}}  \\
   \frac{d}{dt}   <math>{\bf{\hat L}}</math>
+
   \frac{d}{dt} {\bf{\hat L}}  
   &= \gamma   <math>{\bf{\hat L}}</math> \times   <math>{\bf{B}}</math>
+
   &= \gamma {\bf{\hat L}}  \times {\bf{B}}  
\end{align}
+
\end{align}</math>
 
These are just like the classical equations of motion
 
These are just like the classical equations of motion
\ref{eq:classical_precession_in_static_field}, but here they describe the
+
<xr id="eq:classical_precession_in_static_field"/>, but here they describe the
 
precession of the operator for the magnetic moment <math> {\bf{\hat\mu}} </math> or for the
 
precession of the operator for the magnetic moment <math> {\bf{\hat\mu}} </math> or for the
 
angular momentum <math> {\bf{\hat L}} </math> about the magnetic field at the (Larmor)
 
angular momentum <math> {\bf{\hat L}} </math> about the magnetic field at the (Larmor)
 
angular frequency <math>\omega_L=\gamma B_0</math>.
 
angular frequency <math>\omega_L=\gamma B_0</math>.
Note that
+
 
\begin{itemize}
+
Note that:
\item
+
 
Just as in the classical model, these operator equations are
+
* Just as in the classical model, these operator equations are exact; we have not neglected any higher order terms.
exact; we have not neglected any higher order terms.
+
 
\item
+
* Since the equations of motion hold for the operator, they must hold for the expectation value
Since the equations of motion hold for the operator, they must hold for
 
the expectation value
 
 
:<math>
 
:<math>
     \avg{\dot{ {\bf{\hat L}} }}=\gamma\avg{ {\bf{\hat L}} }\times {\bf{B}}  
+
     \langle{\dot{ {\bf{\hat L}} }}\rangle =\gamma\langle{ {\bf{\hat L}} }\rangle\times {\bf{B}}  
 
</math>
 
</math>
\item
+
 
We have not made use of any special relations for a spin-<math>1/2</math> system, but
+
* We have not made use of any special relations for a spin-<math>1/2</math> system, but just the general commutation relation for angular momentum.  Therefore the result, precession about the magnetic field at the Larmor frequency, remains true for any value of angular momentum <math>l</math>.
just the general commutation relation for angular momentum.  Therefore the
+
 
result, precession about the magnetic field at the Larmor frequency, remains
+
* A spin-<math>1/2</math> system has two energy levels, and the two-level problem with coupling between two levels can be mapped onto the problem for a spin in a magnetic field, for which we have developed a good classical intuition.
true for any value of angular momentum <math>l</math>.
+
 
\item
+
* If coupling between two or more angular momenta or spins within an atom results in an angular momentum <math>F>1/2</math>, the time evolution of this angular momentum in an external field is governed by the same physics as for the two-level system.  This is true as long as the applied magnetic field is not large enough to break the coupling between the angular momenta; a situation known as the Zeeman regime.  Note that if the coupled angular momenta have different gyromagnetic ratios, the gyromagnetic ratio for the composite angular momentum is different from those of the constituents.
A spin-<math>1/2</math> system has two energy levels, and the two-level problem with
+
 
coupling between two levels can be mapped onto the problem for a spin in a
+
* For large magnetic field the interaction of the individual constituents with the magnetic field dominates, and they precess separately about the magnetic field.  This is the Paschen-Back regime.  
magnetic field, for which we have developed a good classical intuition.
+
 
\item
+
* An even more interesting composite angular momentum arises when <math>N</math> two-level atoms are coupled symmetrically to an external field.  In this case we have an effective angular momentum <math>L=N/2</math> for the symmetric coupling:
If coupling between two or more angular momenta or spins within an atom
+
 
results in an angular momentum <math>F>1/2</math>, the time evolution of this angular
+
<blockquote>
momentum in an external field is governed by the same physics as for the
+
::[[Image:resonances-Dicke-states.png|thumb|600px|none|]]
two-level system.  This is true as long as the applied magnetic field is not
+
Level structure diagram for <math>n</math> two-level atoms in a basis of symmetric states <ref name="Dicke1954">R. H. Dicke. Coherence in spontaneous radiation processes. Phys. Rev., 93(1):99, Jan 1954.</ref>.  The leftmost column corresponds to an effective spin-<math>n/2</math> object.  Other columns correspond to manifolds of symmetric states of the <math>n</math> atoms with lower total effective angular momentum.
large enough to break the coupling between the angular momenta; a situation
+
</blockquote>
known as the Zeeman regime.  Note that if the coupled angular momenta have
+
: Again the equation of motion for the composite angular momentum <math> {\bf{\hat L}} </math> is a precession.  This is the problem considered in Dicke's famous paper <ref name="Dicke1954">R. H. Dicke. Coherence in spontaneous radiation processes. Phys. Rev., 93(1):99, Jan 1954.</ref>, in which he shows that this collective precession can give rise to massively enhanced couplings to external fields ("superradiance") due to constructive interference between the individual atoms.
different gyromagnetic ratios, the gyromagnetic ratio for the composite angular
+
 
momentum is different from those of the constituents.
+
=== The Two-Level System: Spin-1/2 ===
\item
+
 
For large magnetic field the interaction of the individual constituents
 
with the magnetic field dominates, and they precess separately
 
about the magnetic field.  This is the Paschen-Back regime.
 
\item
 
An even more interesting composite angular momentum arises when
 
<math>N</math> two-level atoms are coupled symmetrically to an external
 
field.  In this case we have an effective angular momentum
 
<math>L=N/2</math> for the symmetric coupling (see Figure \ref{fig:dicke_states}).
 
\begin{figure}
 
::[[Image:resonances-Dicke-states.png|thumb|400px|none|]]
 
\caption{Level structure diagram for <math>n</math> two-level atoms in a basis of symmetric
 
states \cite{Dicke1954}.  The leftmost column corresponds to an effective
 
spin-<math>n/2</math> object.  Other columns correspond to manifolds of symmetric states of
 
the <math>n</math> atoms with lower total effective angular momentum.}
 
 
\end{figure}
 
Again the equation of motion for the composite angular momentum <math> {\bf{\hat L}} </math>
 
is a precession.  This is the problem considered in Dicke's famous paper
 
\cite{Dicke1954}, in which he shows that this collective precession can give
 
rise to massively enhanced couplings to external fields ("superradiance") due
 
to constructive interference between the individual atoms.
 
\end{itemize}
 
=== The Two-Level System: Spin-\texorpdfstring{<math>1/2</math>}{1/2} ===
 
 
Let us now specialize to the two-level system and calculate the time evolution
 
Let us now specialize to the two-level system and calculate the time evolution
 
of the occupation probabilities for the two levels.
 
of the occupation probabilities for the two levels.
\begin{figure}
+
 
 
<blockquote>
 
<blockquote>
::[[Image:resonances-two-level.png|thumb|400px|none|]]
+
<figure id="fig:two_level_spin_half">
\caption{Equivalence of two-level system with spin-<math>1/2</math>.  Note that for
+
[[Image:resonances-two-level.png|thumb|500px|none|]]
<math>\gamma>0</math> the spin-up state (spin aligned with field) is the ground state.  For
+
<caption> Equivalence of two-level system with spin-<math>1/2</math>.  Note that for
an electron, with <math>\gamma<0</math>, spin-up is the excited state.  Be careful, as both
+
<math>\gamma>0</math> the spin-up state (spin aligned with field) is the ground state.  For an electron, with <math>\gamma<0</math>, spin-up is the excited state.  Be careful, as both conventions are used in the literature.
conventions are used in the literature.}
+
</caption>
+
</figure>
 
</blockquote>
 
</blockquote>
\end{figure}
+
 
 
We have that
 
We have that
 
:<math>
 
:<math>
  \left<S_z\right\rangle  
+
  \left\langle S_z\right\rangle  
 
=\frac{\hbar}{2}\left(P_\uparrow-P_\downarrow\right)
 
=\frac{\hbar}{2}\left(P_\uparrow-P_\downarrow\right)
 
=\frac{\hbar}{2}\left(P_g-P_e\right)
 
=\frac{\hbar}{2}\left(P_g-P_e\right)
Line 710: Line 738:
 
where in the last equation we have used the fact that <math>P_e+P_g=1</math>.  The signs
 
where in the last equation we have used the fact that <math>P_e+P_g=1</math>.  The signs
 
are chosen for a spin with <math>\gamma>0</math>, such as a proton (Figure
 
are chosen for a spin with <math>\gamma>0</math>, such as a proton (Figure
\ref{fig:two_level_spin_half}).  For an electron, or any other spin with
+
<xr id="fig:two_level_spin_half"/>).  For an electron, or any other spin with
 
<math>\gamma<0</math>, the analysis would be the same but for the opposite sign of <math>S_z</math>
 
<math>\gamma<0</math>, the analysis would be the same but for the opposite sign of <math>S_z</math>
 
and the corresponding exchange of <math>\uparrow</math> and <math>\downarrow</math>.  If the system is
 
and the corresponding exchange of <math>\uparrow</math> and <math>\downarrow</math>.  If the system is
initially in the ground state, <math>P_g(t=0)=1</math> (or the spin along <math>+\vctr{\hat
+
initially in the ground state, <math>P_g(t=0)=1</math> (or the spin along
e}_z</math>, <math>S_z(0)=+\hbar/2</math>), the expectation value obeys the classical
+
<math>+ {\bf{\hat e}} _z</math>, <math>S_z(0)=+\hbar/2</math>), the expectation value obeys the classical
equation of motion \ref{eq:classical_rabi_flopping}:
+
equation of motion <xr id="eq:classical_rabi_flopping"/>:
\begin{align}
+
<equation id="eq:rabi_transition_probability" noautocaption>
 +
<span style="float:right; display:block;"><caption>(%i)</caption></span>
 +
<math>\begin{align}  
 
   P_e(t)
 
   P_e(t)
   &= \frac{1}{2} - \frac{1}{\hbar}   <math>\left<S_z\right\rangle</math>
+
   &= \frac{1}{2} - \frac{1}{\hbar} \left\langle S_z\right\rangle  
 
   = \frac{1}{2}
 
   = \frac{1}{2}
     - \frac{ <math>\left<S_z(0)\right\rangle</math> }{\hbar}
+
     - \frac{ \left\langle S_z(0)\right\rangle }{\hbar}
 
       \left(1 - 2 \frac{\omega_R^2}{\Omega_R^2} \sin^2
 
       \left(1 - 2 \frac{\omega_R^2}{\Omega_R^2} \sin^2
       \frac{\Omega_R t}{2}\right) \notag \\
+
       \frac{\Omega_R t}{2}\right)   \\
 
   P_e(t)
 
   P_e(t)
 
   &= \frac{\omega_R^2}{\Omega_R^2} sin^2 \left(\frac{\Omega_R t}{2}\right)
 
   &= \frac{\omega_R^2}{\Omega_R^2} sin^2 \left(\frac{\Omega_R t}{2}\right)
 
    
 
    
\end{align}
+
\end{align}</math>
Equation \ref{eqn:rabi_transition_probability} is the probability to find system
+
</equation>
 +
 
 +
Equation <xr id="eq:rabi_transition_probability"/> is the probability to find system
 
in the excited state at time <math>t</math> if it was in ground state at time <math>t=0</math>.
 
in the excited state at time <math>t</math> if it was in ground state at time <math>t=0</math>.
Figure \ref{fig:rabi_signal} shows a real-world example of such an oscillation.
+
<xr id="fig:rabi_signal"/> shows a real-world example of such an oscillation.
\begin{figure}
+
 
 
<blockquote>
 
<blockquote>
::[[Image:resonances-Rabi.png|thumb|400px|none|]]
+
<figure id="fig:rabi_signal">
\caption{Rabi oscillation signal taken in the Vuleti\'{c} lab shortly after this
+
[[Image:resonances-Rabi.png|thumb|400px|none|]]
 +
<caption> Rabi oscillation signal taken in the Vuleti\'{c} lab shortly after this
 
topic was covered in lecture in 2008.  The amplitude of the oscillations decays
 
topic was covered in lecture in 2008.  The amplitude of the oscillations decays
 
with time due to spatial variations in the strength of the drive field (and
 
with time due to spatial variations in the strength of the drive field (and
 
hence of the Rabi frequency), so that the different atoms drift out of phase
 
hence of the Rabi frequency), so that the different atoms drift out of phase
with each other.}
+
with each other.
+
</caption>
 +
</figure>
 
</blockquote>
 
</blockquote>
\end{figure}
+
 
 
=== Matrix form of Hamiltonian ===
 
=== Matrix form of Hamiltonian ===
 
With the matrix representation
 
With the matrix representation
\begin{align*}
+
:<math>\begin{align}  
    <math>\left|e\right\rangle</math>
+
  \left|e\right\rangle  
   &=   <math>\left|S_z = - \frac{1}{2}\right\rangle</math>
+
   &= \left|S_z = - \frac{1}{2}\right\rangle  
 
   = \begin{pmatrix} 1 \\ 0 \end{pmatrix} \\
 
   = \begin{pmatrix} 1 \\ 0 \end{pmatrix} \\
    <math>\left|g\right\rangle</math>
+
  \left|g\right\rangle  
   &=   <math>\left|S_z = + \frac{1}{2}\right\rangle</math>
+
   &= \left|S_z = + \frac{1}{2}\right\rangle  
 
   = \begin{pmatrix} 0 \\ 1 \end{pmatrix}
 
   = \begin{pmatrix} 0 \\ 1 \end{pmatrix}
\end{align*}
+
\end{align}</math>
 
we can write the Hamiltonian <math>H_0</math> associated with the static
 
we can write the Hamiltonian <math>H_0</math> associated with the static
 
field <math> {\bf{B}} _0 = B_0  {\bf{\hat e}} _z</math> as
 
field <math> {\bf{B}} _0 = B_0  {\bf{\hat e}} _z</math> as
Line 757: Line 791:
 
   = -  {\bf{\hat\mu}}  \cdot  {\bf{B}} _0
 
   = -  {\bf{\hat\mu}}  \cdot  {\bf{B}} _0
 
   = - \gamma \hat{S}_z B_0
 
   = - \gamma \hat{S}_z B_0
   = - \hbar \omega_0 \frac{\hat{S}_z}{\hbar}
+
   = \hbar \omega_0 \frac{\hat{S}_z}{\hbar}
 
   = \frac{1}{2} \hbar \omega_0
 
   = \frac{1}{2} \hbar \omega_0
 
     \begin{pmatrix}
 
     \begin{pmatrix}
Line 765: Line 799:
 
   = \frac{1}{2} \hbar \omega_0 \hat{\sigma}_z
 
   = \frac{1}{2} \hbar \omega_0 \hat{\sigma}_z
 
</math>
 
</math>
where <math>\omega_0=\gamma B_0</math> is the Larmor frequency, and
+
where <math>\omega_0=-\gamma B_0</math> is the Larmor frequency (recall that <math> \gamma </math> is negative for an electron, making <math>\omega_0</math> positive), and
 
:<math>
 
:<math>
 
\hat{\sigma}_z=
 
\hat{\sigma}_z=
Line 790: Line 824:
 
which describes a precession with angluar frequency <math>\omega_0</math>.
 
which describes a precession with angluar frequency <math>\omega_0</math>.
 
The field <math> {\bf{B}} _1</math>, rotating at <math>\omega</math> in the <math>X-Y</math> plane corresponds to
 
The field <math> {\bf{B}} _1</math>, rotating at <math>\omega</math> in the <math>X-Y</math> plane corresponds to
\begin{align}
+
:<math>\begin{align}  
 
   \hat{H}_1
 
   \hat{H}_1
   &= - <math>{\bf{\hat\mu}}</math> \cdot <math>{\bf{B}}</math> _1(t)
+
   &= - {\bf{\hat\mu}} \cdot {\bf{B}} _1(t)
     =- <math>{\bf{\hat\mu}}</math> \cdot\frac{\omega_R}{\gamma}
+
     =- {\bf{\hat\mu}} \cdot\frac{\omega_R}{\gamma}
       \left(- <math>{\bf{\hat e}}</math> _x \cos\omega t-   <math>{\bf{\hat e}}</math> _y \sin\omega t\right)
+
       \left(- {\bf{\hat e}} _x \cos\omega t- {\bf{\hat e}} _y \sin\omega t\right)
      \notag \\
+
        \\
   &= \omega_R\left(\hat{S}_x \cos\omega t + \hat{S}_y \sin\omega t\right) \notag
+
   &= \omega_R\left(\hat{S}_x \cos\omega t + \hat{S}_y \sin\omega t\right)
 
   \\
 
   \\
 
   &= \frac{\hbar\omega_R}{2}
 
   &= \frac{\hbar\omega_R}{2}
 
     \left(\hat{\sigma}_x \cos\omega t + \hat{\sigma}_y \sin\omega t\right)
 
     \left(\hat{\sigma}_x \cos\omega t + \hat{\sigma}_y \sin\omega t\right)
    \notag \\
+
      \\
 
   &= \frac{\hbar\omega_R}{2}
 
   &= \frac{\hbar\omega_R}{2}
 
     \left(
 
     \left(
 
       \begin{pmatrix} 0 & 1 \\ 1 & 0 \end{pmatrix}\cos\omega t
 
       \begin{pmatrix} 0 & 1 \\ 1 & 0 \end{pmatrix}\cos\omega t
 
       + \begin{pmatrix} 0 & -i \\ i & 0    \end{pmatrix}\sin\omega t
 
       + \begin{pmatrix} 0 & -i \\ i & 0    \end{pmatrix}\sin\omega t
     \right) \notag \\
+
     \right)   \\
 
   \hat{H}_1
 
   \hat{H}_1
 
   &= \frac{\hbar\omega_R}{2}
 
   &= \frac{\hbar\omega_R}{2}
Line 812: Line 846:
 
       e^{i\omega t} & 0
 
       e^{i\omega t} & 0
 
     \end{pmatrix}
 
     \end{pmatrix}
\end{align}
+
\end{align}</math>
 
where have used the Pauli spin matrices <math>\sigma_x</math>, <math>\sigma_y</math>. The full
 
where have used the Pauli spin matrices <math>\sigma_x</math>, <math>\sigma_y</math>. The full
 
Hamiltonian is thus given by
 
Hamiltonian is thus given by
:<math>
+
 
 +
:<equation id="eq:dressed_atom_hamiltonian" noautocaption>
 +
<span style="float:right; display:block;"><caption>(%i)</caption></span>
 +
<math>
 
\hat{H}=\frac{\hbar}{2}
 
\hat{H}=\frac{\hbar}{2}
 
   \begin{pmatrix}
 
   \begin{pmatrix}
 
     +\omega_0 & \omega_R e^{-i \omega t} \\
 
     +\omega_0 & \omega_R e^{-i \omega t} \\
     \omega_R e^{-i \omega t} & - \omega_0
+
     \omega_R e^{i \omega t} & - \omega_0
 
   \end{pmatrix}
 
   \end{pmatrix}
 
</math>
 
</math>
 +
</equation>
 
This is the famous "dressed atom" Hamiltonian in the so-called "rotating wave
 
This is the famous "dressed atom" Hamiltonian in the so-called "rotating wave
approximation".  Its eigenstates and eigenvalues provide a very elegant, very
+
approximation".  However, note that in the treatment here there are no approximations; it is exact.  Its eigenstates and eigenvalues provide a very elegant, very
 
intuitive solution to the two-state problem.
 
intuitive solution to the two-state problem.
=== Solution of the Schr\"{o ===
+
 
Spin-\texorpdfstring{<math>1/2</math>}{1/2} in the Interaction Representation}
+
=== Solution of the Schrodinger Equation for Spin-1/2 in the Rotating Frame ===
The interaction representation consists of expanding the state <math> \left|\psi(t)\right\rangle </math>
+
The time-dependence of the above Hamiltonian can be eliminated by applying a unitary transformation to the system.  Namely, a rotation about the z-axis accomplishes this.  Call this rotation operator <math>\bf{R}</math>, which can be expressed
 +
:<math>\begin{align}
 +
  {\bf{R}}
 +
  &= e^{i S_z \theta/\hbar} \\
 +
  &=
 +
  \begin{pmatrix}
 +
      e^{i \omega t/2} & 0 \\
 +
      0 & e^{-i \omega t/2}
 +
  \end{pmatrix},
 +
\end{align}</math>
 +
where we let <math>\theta = \omega t</math>. Then the transformed Hamiltonian
 +
:<math>\begin{align}
 +
  H' = {\bf{R}}H\,{\bf{R}}^{\dagger}-i\hbar\,{\bf{R}}\frac{d\bf{R}^{\dagger}}{dt},
 +
\end{align}</math>
 +
is
 +
:<math>\begin{align}
 +
  H'
 +
  &= \frac{\hbar}{2}
 +
  \begin{pmatrix}
 +
      -\delta & \omega_{\rm{R}} \\
 +
      \omega_{\rm{R}} & \delta
 +
  \end{pmatrix},
 +
\end{align}</math>
 +
where <math>\delta = \omega - \omega_0</math>.  This time-independent Hamiltonian can be diagonalized exactly to obtain the eigenenergies and eigenstates.  The general solution has the form,
 +
:<math>\begin{align}
 +
  \psi(t) = a_g(t) | g \rangle + a_e(t) | e \rangle.
 +
\end{align}</math>
 +
In particular, the case <math>a_g(0) = 1</math> and <math>a_e(0) = 0</math> leads to the probability of finding the atom in the excited state to be
 +
:<math>\begin{align}
 +
  P_e(t) = |a_e(t)|^2 = \frac{\omega^2_{\rm R}}{\Omega^2_{\rm R}} \sin^2 \left( \frac{\Omega_{\rm R} t}{2} \right),
 +
\end{align}</math>
 +
where <math>\Omega_{\rm R} = \sqrt{\delta^2 + \omega^2_{\rm R}}</math> is the generalized Rabi frequency.  This form is identical to the one obtained in the classical picture.
 +
 
 +
=== Solution of the Schrodinger Equation for Spin-1/2 in the Interaction Representation ===
 +
 
 +
The same system can be solved by a more brute-force method by isolating the "bare" time-dependence first and then using substitutions.  The interaction representation consists of expanding the state <math> \left|\psi(t)\right\rangle </math>
 
in terms of the eigenstates <math> \left|e\right\rangle </math>, <math> \left|g\right\rangle </math> of the Hamiltonian <math>H_0</math>,
 
in terms of the eigenstates <math> \left|e\right\rangle </math>, <math> \left|g\right\rangle </math> of the Hamiltonian <math>H_0</math>,
 
including their known time dependence <math>e^{iH_0 t/\hbar}</math> due to <math>H_0</math>.
 
including their known time dependence <math>e^{iH_0 t/\hbar}</math> due to <math>H_0</math>.
Line 834: Line 907:
 
  \left|\psi(t)\right\rangle =a_e(t) \left|e\right\rangle e^{-i\omega_0t/2}+a_g(t) \left|g\right\rangle e^{i\omega_0t/2}
 
  \left|\psi(t)\right\rangle =a_e(t) \left|e\right\rangle e^{-i\omega_0t/2}+a_g(t) \left|g\right\rangle e^{i\omega_0t/2}
 
</math>
 
</math>
Substituting this into the Schr\"{o}dinger equation
+
Substituting this into the Schrodinger equation
 
:<math>
 
:<math>
 
i\hbar\frac{d}{dt}  \left|\psi(t)\right\rangle =\left(H_0+H_1\right) \left|\psi(t)\right\rangle  
 
i\hbar\frac{d}{dt}  \left|\psi(t)\right\rangle =\left(H_0+H_1\right) \left|\psi(t)\right\rangle  
 
</math>
 
</math>
 
then results in the equations of motion for the coefficients
 
then results in the equations of motion for the coefficients
\begin{align*}
+
:<math>\begin{align}  
i\dot{a}_e&= \frac{\omega_R}{2}e^{i\left(\omega_0-\omega\right)t}a_g \\
+
i\dot{a}_g&= \frac{\omega_R}{2}e^{i\left(\omega-\omega_0\right)t}a_e \\
i\dot{a}_g&= \frac{\omega_R}{2}e^{-i\left(\omega_0-\omega\right)t}a_e
+
i\dot{a}_e&= \frac{\omega_R}{2}e^{-i\left(\omega-\omega_0\right)t}a_g
\end{align*}
+
\end{align}</math>
 
Where we have used the matrix form of the Hamiltonian,
 
Where we have used the matrix form of the Hamiltonian,
\ref{eq:dressed_atom_hamiltonian}.  Introducing the detuning
+
<xr id="eq:dressed_atom_hamiltonian"/>.  Introducing the detuning
 
<math>\delta=\omega-\omega_0</math>, we have
 
<math>\delta=\omega-\omega_0</math>, we have
\begin{align*}
+
:<math>\begin{align}  
 
i\dot{a}_g&= \frac{\omega_R}{2}e^{i\delta t}a_e \\
 
i\dot{a}_g&= \frac{\omega_R}{2}e^{i\delta t}a_e \\
 
i\dot{a}_e&= \frac{\omega_R}{2}e^{-i\delta t}a_g
 
i\dot{a}_e&= \frac{\omega_R}{2}e^{-i\delta t}a_g
\end{align*}
+
\end{align}</math>
The explicit time dependence can be eliminated by the sustitution
+
The explicit time dependence can be eliminated by the substitution
\begin{align*}
+
:<math>\begin{align}  
 
b_g&= e^{-i\delta t/2}a_g \\
 
b_g&= e^{-i\delta t/2}a_g \\
 
b_e&= e^{i\delta t/2}a_e
 
b_e&= e^{i\delta t/2}a_e
\end{align*}
+
\end{align}</math>
 
As you will show (or have shown) in the problem set, this leads to solutions for
 
As you will show (or have shown) in the problem set, this leads to solutions for
 
<math>b_{g,e}</math> given by
 
<math>b_{g,e}</math> given by
\begin{align*}
+
:<math>\begin{align}  
 
b_g(t)&= e^{i\Omega_R t/2}B_1+e^{-i\Omega_R t/2}B_2 \\
 
b_g(t)&= e^{i\Omega_R t/2}B_1+e^{-i\Omega_R t/2}B_2 \\
b_e(t)&= \frac{\omega_R}{\delta-\Omega_R}e^{i\Omega t/2}B_1
+
b_e(t)&= \frac{\omega_R}{\delta-\Omega_R}e^{i\Omega_R t/2}B_1
 
         +\frac{\omega_R}{\delta+\Omega_R}e^{-i\Omega_R t/2}B_2
 
         +\frac{\omega_R}{\delta+\Omega_R}e^{-i\Omega_R t/2}B_2
\end{align*}
+
\end{align}</math>
 
with two constants that are determined by the initial conditions.
 
with two constants that are determined by the initial conditions.
 
For <math>a_g(t=0)=1</math> we find
 
For <math>a_g(t=0)=1</math> we find
Line 869: Line 942:
 
as already derived from the fact that the expectation value for
 
as already derived from the fact that the expectation value for
 
the magnetic moment obeys the classical equation.
 
the magnetic moment obeys the classical equation.
=== Atomic Clocks and the Ramsey Method ===
+
 
When comparing the Hamiltonian for a spin-<math>1/2</math> in a magnetic field to that of a
+
=== "Rapid" Adiabiatic Passage (Quantum Treatment) ===
two-level system with a coupling between the two levels characterized by the
+
 
strength <math>\omega_R</math> and frequency <math>\omega</math>, we see that the energy spacing
+
Quantum mechanically, we have seen that the Hamiltonian of an interacting two-level system can be written as
between <math> \left|e\right\rangle </math> and <math> \left|g\right\rangle </math> corresponds to the Larmor frequency <math>\omega_0</math>
+
:<math>\begin{align}
in the static fieldThis spacing can provide a frequency or time reference if
+
  H'
perturbations affecting <math>\omega_0</math> are sufficiently well controlled. For
+
  &= \frac{\hbar}{2}
instance, the time unit "second" is defined via the transition frequency
+
  \begin{pmatrix}
between two hyperfine states in the electronic ground state of the caesium atom,
+
      -\delta & \omega_{\rm{R}} \\
which is near \unit{9.2}{\giga\hertz} in the microwave domain.  The task of an
+
      \omega_{\rm{R}} & \delta
atomic clock is then to measure this frequency accurately by trying to tune a
+
  \end{pmatrix},
frequency source (the frequency <math>\omega</math> of the rotating field <math>B_1</math> in the spin
+
\end{align}</math>
picture) to the atomic frequency <math>\omega_0</math>.  Equivalently, we want to find the
+
where <math>\delta \equiv \omega - \omega_0</math>.  Let us call the "bare" i.e. unperturbed, eigenstates of the Hamiltonian as <math>|\uparrow \rangle</math> and <math>|\downarrow \rangle</math>. If you examine the eigenstates of this Hamiltonian, you will realize that by changing the frequency of your coupling, the eigenstates will "evolve" from e.g. <math>|\uparrow \rangle</math> to <math>|\downarrow \rangle</math>, or vice versa.  This can be accomplished by sweeping <math>\omega</math> at a rate <math>\dot{\omega}</math>.  This leads to the Landau-Zener problem of a sweep through an avoided crossing.
frequency <math>\omega</math> such that the detuning <math>\delta=\omega-\omega_0</math> is equal to
+
 
zero.
+
<blockquote>
Starting with an atom in <math> \left|g\right\rangle </math> (spin along <math>+ {\bf{\hat e}} _z</math> for
+
::[[Image:Landau-zener-new.PNG|thumb|400px|none|]]
<math>\gamma>0</math>), we could try to find the resonance frequency by noting that
+
An avoided crossingA system on one level can jump to the other if the parameter <math>q</math> that governs the energy levels is swept sufficiently rapidly.
according to
+
</blockquote>
 +
 
 +
Whether or not the system follows an energy level adiabatically
 +
depends on how rapidly the energy is changed, compared to the
 +
minimum energy separation. To cast the problem in quantum
 +
mechanical terms, imagine two non-interacting states whose energy
 +
separation, <math>\omega</math>, depends on some parameter <math>x</math> which varies
 +
linearly in time, and vanishes for some value <math>x_0</math>. Now add a
 +
perturbation having an off-diagonal matrix element <math>V</math> which is
 +
independent of <math>x</math>, so that the energies at <math>x_0</math> are <math>\pm~V
 +
=\pm \hbar \omega_{\rm R}/2</math>.  The probability that the system will
 +
"jump" from one adiabatic level to the other after passing
 +
through the "avoided crossing" (i.e., the probability of
 +
non-adiabatic behavior)
 +
is
 +
:<math>
 +
P_\text{na} =e^{-2\pi\Gamma}
 +
</math>
 +
where
 +
:<math>
 +
\Gamma = \frac{| \omega_{\rm R} | ^2}{4 \dot\omega},
 +
</math>
 +
and <math>\dot\omega \equiv d\omega /dt</math>.  This result was originally obtained by Landau and Zener. The jumping of
 +
a system as it travels across an avoided crossing is called the
 +
Landau-Zener effect. Inserting the parameters for our
 +
magnetic field problem, we have
 +
 
 
:<math>
 
:<math>
P_e(t)=\frac{\omega_R^2}{\omega_R^2+\delta^2}
+
P_{\rm na} = \exp \left( -\frac{\pi}{2} \frac{\omega_R^2} {\left| \dot\omega\right|}\right)
  sin^2\left(\sqrt{\omega_R^2+\delta^2}\,\frac{t}{2}\right)
 
 
</math>
 
</math>
the population of the upper state is maximized for <math>\delta=0</math> (i.e.  the
+
 
precession of the spin to the <math>- {\bf{\hat e}} _z</math> direction is only complete on
+
Note that when <math>\omega^2_{\rm R} \gg \left| \dot\omega\right|</math> is satisfied, the probability of non-adiabatic behavior is
resonance). This is the so-called Rabi method. It suffers from a number of
+
exponentially small. This agrees with our classical analysis.
drawbacks.  For one, the signal is only quadratic in the detuning <math>\delta</math>, i.e.
+
 
the method is relatively insensitive near <math>\delta=0</math>Furthermore, the optimum
+
Let us now consider a diabatic sweep, where the probability to make a transition across the crossing is non-negligible, but small. This process can be described by the Schroedinger equation in a coherent wayIn particular,
time <math>t</math> depends on the strength <math>\omega_R</math> of the coupling (i.e. the strength
+
:<math>
<math>B_1</math> of the rotating field), so fluctuations in <math>\omega_R</math> can be mistaken for
+
\dot{a}_2 = i \frac{H_{12}}{\hbar} a_1 \Rightarrow a_2 = \frac{1}{2}\omega_{\rm R} t \Rightarrow P \approx |a_2|^2 \approx \omega^2_{\rm R} t^2_{\rm eff},
changes in <math>\delta</math>.  Finally the coupling by <math>\omega_R</math> to other levels can
+
</math>
lead to level shifts that are not intrinsic to the atom, but depend on the
+
where <math>t_{\rm eff}</math> is the effective sweep duration, or the dephasing time <math>\Delta t</math>. This is determined by
applied drive <math>\omega_R</math> (Figure \ref{fig:rabi_third_level}).
+
:<math>
\begin{figure}
+
\Delta \omega \Delta t \approx \pi,
<blockquote>
+
</math>
::[[Image:resonances-rabi-third-level.png|thumb|400px|none|]]
+
where <math>\Delta \omega = \dot{\omega} \Delta t</math>.  This then gives us <math>\Delta t \approx \sqrt{1/\dot{\omega}}</math>.  Then we get
</blockquote>
+
:<math>
\caption{The drive used for Rabi flopping within the  <math>\left|e\right\rangle</math> ,  <math>\left|g\right\rangle</math>  system can
+
P \approx \omega^2_{\rm R} t^2_{\rm eff} = \omega^2_{\rm R}/\dot{\omega}.
also off-resonantly couple one or both levels to other states, perturbing the
+
</math>
transition frequency <math>\omega_0</math>.}
+
Note that the sum of the probability to undergo a transition and the probability to not undergo a transition must equal oneThis means <math>P = 1 - P_{\rm na}</math>.  Using our expression for <math>P_{\rm na}</math> we obtained above, we find
+
:<math>
\end{figure}
+
P = 1 - P_{\rm na} = 2 \pi \Gamma \approx \frac{\omega^2_{\rm R}}{\dot{\omega}}.
Norman Ramsey invented an alternative method (the so-called "separated
+
</math>
oscillatory fields method", known for short as the "Ramsey method"
+
Therefore we've determined the probability to undergo a diabatic transition two different ways and see that they agree.
\cite{Ramsey1949,Ramsey1950}, for which he received the Nobel prize), that fixes
+
 
all of these problems. It leads to a signal that is linear rather than quadratic
+
Incidentally the "rapid" in adiabatic rapid passage is something of a
in the detuning <math>\delta</math>, does not require tuning the measurement time to match
+
misnomerThe technique was originally developed in nuclear magnetic
the applied field strength <math>\omega_R=\gamma B_1</math>, and, most importantly,
+
resonance in which thermal relaxation effects destroy the spin
eliminates level shifts due to <math>\omega_R</math> altogether.
+
polarization if one does not invert the population sufficiently rapidly.
The method is as follows.  Instead of applying a pulse for a time t that
+
In the absence of such relaxation processes one can take as long as one
corresponds to Rabi rotation of the spin by <math>\pi</math> (called a <math>\pi</math> pulse), the
+
pleases to traverse the anticrossings, and the slower the crossing the
pulse is applied for half that time, corresponding to the Rabi rotation of the
+
less the probability of jumping.
spin by <math>\pi/2</math> into the <math>X-Y</math> plane (<math>\pi/2</math> pulse)Then the applied field
+
 
<math>B_1</math> is turned off and the system is left to precess in the static field <math>B_0</math>
+
== Decoherence Processes, Mixed States, Density Matrices ==
(or at its natural frequency <math>\omega_0</math>) for a measurement time <math>T</math>.  Finally, a
+
 
second <math>\pi/2</math> pulse, identical to the original one, is applied (see Figure
+
The purely Hamiltonian evolution described by the Schrodinger Equation
\ref{fig:ramsey_sequence}).
 
\begin{figure}
 
<blockquote>
 
::[[Image:resonances-ramsey-seq.png|thumb|400px|none|]]
 
\caption{Ramsey sequence}
 
 
</blockquote>
 
\end{figure}
 
The signal is the <math> {\bf{\hat e}} _z</math> component of the spin after the second
 
interactionThe signal after the second <math>\pi/2</math> pulse is an oscillating signal
 
in <math>T\delta</math>, depending on how much phase the spin has acquired relative to the
 
local oscillator (the microwave signal generator at frequency <math>\omega</math>).
 
Examples of such curves are shown in Figures \ref{fig:ramsey_signal} and
 
\ref{fig:ramsey_vs_freq}.
 
\begin{figure}
 
<blockquote>
 
::[[Image:resonances-Ramsey|thumb|400px|none|]]
 
\caption{Ramsey oscillation signal as a function of time taken in the
 
Vuleti\'{c} lab in 2007.  The drive field was deliberately detuned from
 
resonance so that the oscillation at the detuning frequency would be visible.}
 
</blockquote>
 
 
\end{figure}
 
\begin{figure}
 
<blockquote>
 
::[[Image:resonances-Ramsey-vs-freq.png|thumb|400px|none|]]
 
\caption{Experimental data from Ramsey's original paper \cite{Ramsey1950},
 
showing the signal as a function of frequencyNote the narrow oscillation,
 
whose width is set by the measurement time <math>T</math>, superimposed on the much broader
 
background set up by the inhomogeneously broadened <math>\pi/2</math> pulses.}
 
</blockquote>
 
 
\end{figure}
 
At the zero crossings we have maximum sensitivity of the signal with respect to
 
frequency changes.  Note that the signal as a function of <math>T</math> looks similar to
 
Rabi flopping.  However, there the zero crossing measure the Rabi frequency, not
 
<math>\delta=\omega-\omega_0</math>.
 
== Decoherence Processes, Mixed States, Density Matrix ==
 
The purely Hamiltonian evolution described by the Schr\"{o}dinger Equation
 
 
leaves the system in a pure state.  However, often we have to deal with
 
leaves the system in a pure state.  However, often we have to deal with
 
incoherent processes such as the uncontrolled loss or addition of atoms, or
 
incoherent processes such as the uncontrolled loss or addition of atoms, or
Line 971: Line 1,030:
 
E_{g,e}\rightarrow E_{g,e}+i\frac{\Gamma_{g,e}t}{2}
 
E_{g,e}\rightarrow E_{g,e}+i\frac{\Gamma_{g,e}t}{2}
 
</math>
 
</math>
The decay of the norm <math> \left\langle\psi\vert\psi\right\rangle </math> corresponds to decay out of the
+
The decay of the norm <math> \left\langle \psi\vert\psi\right\rangle </math> corresponds to decay out of the
<math> \left|g\right\rangle </math>, <math> \left|e\right\rangle </math> system, as in figure \ref{fig:decay_out}.
+
<math> \left|g\right\rangle </math>, <math> \left|e\right\rangle </math> system, as in <xr id="fig:decay_out"/>.
\begin{figure}
+
 
 
<blockquote>
 
<blockquote>
::[[Image:resonances-decay-out.png|thumb|400px|none|]]
+
<figure id="fig:decay_out">
\caption{Decay out of the  <math>\left|e\right\rangle</math>    <math>\left|g\right\rangle</math>  system, which can be modelled by a
+
[[Image:resonances-decay-out.png|thumb|400px|none|]]
 +
<caption> Decay out of the  <math>\left|e\right\rangle</math>    <math>\left|g\right\rangle</math>  system, which can be modelled by a
 
non-Hermitian Hamiltonian, the imaginary part of the eigenvalue corresponding to
 
non-Hermitian Hamiltonian, the imaginary part of the eigenvalue corresponding to
a decay rate.}
+
a decay rate.
+
</caption>
 +
</figure>
 
</blockquote>
 
</blockquote>
\end{figure}
+
 
 
However, other processes, such as spontaneous decay from <math> \left|e\right\rangle </math> to <math> \left|g\right\rangle </math>
 
However, other processes, such as spontaneous decay from <math> \left|e\right\rangle </math> to <math> \left|g\right\rangle </math>
 
or loss of coherence (well-defined phase relationship) between <math> \left|e\right\rangle </math>
 
or loss of coherence (well-defined phase relationship) between <math> \left|e\right\rangle </math>
Line 994: Line 1,055:
 
operator for that statistical mixture, or ensemble average.
 
operator for that statistical mixture, or ensemble average.
 
:<math>
 
:<math>
\hat{\rho}=\Sigma P_i \left|\psi_i\right\rangle  \left\langle\psi_i\right| =\overline{ \left|\psi\right\rangle  \left\langle\psi\right| }
+
\hat{\rho}=\Sigma P_i \left|\psi_i\right\rangle  \left\langle \psi_i\right| =\overline{ \left|\psi\right\rangle  \left\langle \psi\right| }
 
</math>
 
</math>
From the Schr\"{o}dinger equation it follows that the Hamiltonian evolution of the
+
From the Schrodinger equation it follows that the Hamiltonian evolution of the
 
density operator is governed by
 
density operator is governed by
 
:<math>
 
:<math>
Line 1,006: Line 1,067:
 
The expectation value of any operator is given by
 
The expectation value of any operator is given by
 
:<math>
 
:<math>
  \left<\hat O\right\rangle = Tr \left(\hat O\hat \rho\right)= Tr \left(\hat \rho\hat O\right)
+
  \left\langle \hat O\right\rangle = Tr \left(\hat O\hat \rho\right)= Tr \left(\hat \rho\hat O\right)
 
</math>
 
</math>
 
The expectation value of the unity operator must be 1, so
 
The expectation value of the unity operator must be 1, so
Line 1,014: Line 1,075:
 
elements
 
elements
 
:<math>
 
:<math>
\rho_{n^\prime n}= \left\langlen^\prime\right| \hat \rho \left|n\right\rangle  
+
\rho_{n^\prime n}= \left\langle n^\prime\right| \hat \rho \left|n\right\rangle  
 
</math>
 
</math>
 
and the expectation value of any operator can be written as
 
and the expectation value of any operator can be written as
\begin{align*}
+
:<math>\begin{align}  
  <math>\left<\hat O\right\rangle</math>
+
\left\langle \hat O\right\rangle  
 
&=  Tr \left(\hat O\hat\rho\right)
 
&=  Tr \left(\hat O\hat\rho\right)
=\Sigma_n <math>\left\langlen\right|</math> \hat O\hat \rho <math>\left|n\right\rangle</math>
+
=\Sigma_n \left\langle n\right| \hat O\hat \rho \left|n\right\rangle  
=\Sigma_{n^\prime n} <math>\left\langlen\right|</math> \hat O <math>\left|n^\prime\right\rangle</math>  <math>\left\langlen^\prime\right|</math> \hat \rho <math>\left|n\right\rangle</math> \\
+
=\Sigma_{n^\prime n} \left\langle n\right| \hat O \left|n^\prime\right\rangle \left\langle n^\prime\right| \hat \rho \left|n\right\rangle  \\
  <math>\left<\hat O\right\rangle</math> &= \Sigma_{nn^\prime}O_{nn^\prime}\rho_{n^\prime n}
+
\left\langle \hat O\right\rangle  
\text{ with } O_{nn^\prime}= <math>\left\langlen\right|</math> \hat O <math>\left|n^\prime\right\rangle</math>
+
&= \Sigma_{nn^\prime}O_{nn^\prime}\rho_{n^\prime n}
\end{align*}
+
\text{ with } O_{nn^\prime}= \left\langle n\right| \hat O \left|n^\prime\right\rangle  
 +
\end{align}</math>
 
The diagonal elements of the density matrix (<math>\rho_{n^\prime n}</math>) are called the
 
The diagonal elements of the density matrix (<math>\rho_{n^\prime n}</math>) are called the
 
probabilities since <math>\rho_{nn}</math> is the probability to find the system in state
 
probabilities since <math>\rho_{nn}</math> is the probability to find the system in state
Line 1,033: Line 1,095:
 
<math>A\leq\sqrt{\rho_{nn}\rho_{n^\prime n^\prime}}</math>.  The coherence is maximum when
 
<math>A\leq\sqrt{\rho_{nn}\rho_{n^\prime n^\prime}}</math>.  The coherence is maximum when
 
<math>A=\sqrt{\rho_{nn}\rho_{n^\prime n^\prime}}</math>.  Finally note that the density
 
<math>A=\sqrt{\rho_{nn}\rho_{n^\prime n^\prime}}</math>.  Finally note that the density
operator is hermitian, so that <math>\rho_{n^\prime n} = {\rho_nn^\prime}^\star</math>, as
+
operator is hermitian, so that <math>\rho_{n^\prime n} = \rho_{nn^\prime}^\star</math>, as
 
we would expect for a meaningfully-defined coherence between two states.
 
we would expect for a meaningfully-defined coherence between two states.
 +
 
=== Density Matrix for a Two-Level System and Bloch Vector ===
 
=== Density Matrix for a Two-Level System and Bloch Vector ===
 
We now introduce a slightly different parametrization of the two-level
 
We now introduce a slightly different parametrization of the two-level
Hamiltonian \ref{eq:dressed_atom_hamiltonian} and of the corresponding density
+
Hamiltonian <xr id="eq:dressed_atom_hamiltonian"/> and of the corresponding density
 
matrix:
 
matrix:
\begin{align*}
+
:<math>\begin{align}  
 
H&= \frac{\hbar}{2}
 
H&= \frac{\hbar}{2}
 
   \begin{pmatrix}
 
   \begin{pmatrix}
Line 1,064: Line 1,127:
 
&= \frac{1}{2}
 
&= \frac{1}{2}
 
   \left(r_0\hat 1 + r_1\hat\sigma_x + r_2\hat\sigma_y + r_3 \hat\sigma_z\right)
 
   \left(r_0\hat 1 + r_1\hat\sigma_x + r_2\hat\sigma_y + r_3 \hat\sigma_z\right)
\end{align*}
+
\end{align}</math>
 
In the problem set you will show (or have shown) that the Hamiltonian evolution
 
In the problem set you will show (or have shown) that the Hamiltonian evolution
 
of the density matrix
 
of the density matrix
Line 1,084: Line 1,147:
 
but we have now generalized this result to mixed states, i.e. to ensemble
 
but we have now generalized this result to mixed states, i.e. to ensemble
 
averages that have less than the maximum possible magnetic moment.
 
averages that have less than the maximum possible magnetic moment.
 +
 +
We have just derived the theorem by Feynman, Vernon and Hellwarth (1957) which states that the time evolution of the density matrix for the most general two-level system is isomorphic to the behavior of a classical moment in a suitable time-dependent magnetic field.
 +
 
Note that Hamiltonian evolution does not change the purity of a
 
Note that Hamiltonian evolution does not change the purity of a
 
state: a pure state always remains pure, no matter how violently
 
state: a pure state always remains pure, no matter how violently
Line 1,096: Line 1,162:
 
Since <math>\dot{ {\bf{r}} }\perp {\bf{r}} </math>, the length of <math> {\bf{r}} </math> does not change,
 
Since <math>\dot{ {\bf{r}} }\perp {\bf{r}} </math>, the length of <math> {\bf{r}} </math> does not change,
 
and hence <math> Tr \rho^2</math> is constant in time.
 
and hence <math> Tr \rho^2</math> is constant in time.
\putbib
+
 
 +
=== Phenomenological Treatment of Relaxation: Bloch Equations ===
 +
 
 +
Statistical mechanics tells us the form which the density matrix will
 +
ultimately take, but it does not tell us how the system will get there or
 +
how long it will take.  All we know is that ultimately the density matrix
 +
will thermalize to
 +
:<math>
 +
\rho^T = \frac{1}{Z} e ^{-H_0/kT},
 +
</math>
 +
where Z is the partition function.
 +
 
 +
Since the interactions which ultimately bring thermal equilibrium are
 +
incoherent processes, the density matrix formulation seems like a
 +
natural way to treat them.  Unfortunately in most cases these
 +
interactions are sufficiently complex that this is done
 +
phenomenologically.  For example, the equation of motion for the density
 +
matrix might be modified by the addition of a damping term:
 +
:<math>
 +
\dot{\rho} = \frac{1}{i\hbar} [H, \rho ] - (\rho - \rho^T)/T_e
 +
</math>
 +
 
 +
which would (in the absence of a source of non-equilibrium interactions)
 +
drive the system to equilibrium with time constant <math>T_e</math>.
 +
 
 +
This equation is not sufficiently general to describe the behavior of most
 +
systems studied in resonance physics, which exhibit different decay
 +
times for the energy and phase coherence, called <math>T_1</math> and <math>T_2</math>
 +
respectively.
 +
 
 +
* <math>T_1</math> - decay time for population differences between non-degenerate levels, e.g. for <math>r_3</math> (also called the energy decay time).
 +
* <math>T_2</math> - decay time for coherences (between either degenerate or non-degenerate states), i.e. for <math>r_1</math> or <math>r_2</math>.
 +
 
 +
The reason is that, in general, it requires a weaker interaction to destroy
 +
coherence (the relative phase of the coefficients of different states) than
 +
to destroy the population difference, so some relaxation processes
 +
will relax only the phase, resulting in <math>T_2 < T_1</math>.  (caution: certain
 +
types of collisions violate this generality.)
 +
 
 +
The effects of thermal relaxation with the two decay times
 +
described above are easily incorporated into the vector model for
 +
the 2-level system since the z-component of the population vector
 +
<math>\mathbf{r}</math> represents the population difference
 +
and <math>r_x</math> and <math>r_y</math> represent coherences (i.e. off-diagonal
 +
matrix elements of <math>\rho</math>): The results are
 +
:<math>
 +
\dot{\mathbf{r}}_z =  {\left( \mathbf{\omega}\times \mathbf{r}
 +
\right)_z} - {\left( r_z - r_z^T \right)}/T_1
 +
</math>
 +
:<math>
 +
\dot{\mathbf{r}}_{x,y} = {\left( \mathbf{\omega}\times
 +
\mathbf{r}\right)_{x,y}} - {\left(r_{x,y} - r_{x,y}^T\right)}/T_2
 +
</math>
 +
 
 +
For a magnetic spin system <math>\mathbf{r}</math> corresponds directly to the magnetic
 +
moment <math>{\vec  \mu}</math>.  The above equations were first introduced
 +
by Bloch in this context and are known as the Bloch
 +
equations.
 +
 
 +
The addition of phenomenological decay times does not generalize the
 +
density matrix enough to cover situations where atoms (possibly
 +
state-selected) are added or lost to a system.  This situation can be
 +
covered by the addition of further terms to <math>\dot{\rho}</math>.  Thus a
 +
calculation on a resonance experiment in which state-selected atoms
 +
are added to a two-level system through a tube which also permits atoms to
 +
leave (e.g. a hydrogen maser) might look like
 +
 
 +
:<math>\begin{align}
 +
\dot{\rho} &= \frac{1}{i\hbar} [H, \rho] -
 +
\begin{pmatrix} (\rho_{11} - \rho_{11T})/T_1 & \rho_{12}/T_2 \\
 +
\rho_{21}/T_2 & (\rho_{22}- \rho_{22T})/T_1
 +
\end{pmatrix}
 +
+R \begin{pmatrix} 0 & 0 \\
 +
0 & 1
 +
\end{pmatrix}
 +
- \rho /T_{\rm escape} -
 +
\rho /T_{\rm collision}
 +
\end{align}
 +
</math>
 +
where R is the rate of addition of state-selected atoms.  The last two terms express effects of atom escape from the system and of
 +
collisions (e.g. spin exchange) that can't easily be incorporated in <math>T_1</math> and <math>T_2</math>.
 +
 
 +
The terms representing addition or loss of atoms will not have zero
 +
trace, and consequently will not maintain Tr<math> ( \rho ) = 1</math>.
 +
Physically this is reasonable for systems which gain or lose atoms;
 +
the application of the density matrix to this case shows its power to
 +
deal with complicated situations.  In most applications of the above
 +
equation, one looks for a steady state solution (with <math>\dot{\rho} = 0</math>),
 +
so this does not cause problems.
 +
 
 +
== References ==
 +
 
 +
* Armani2003: D. K. Armani, T. J. Kippenberg, S. M. Spillane, and K. J. Vahala. Ultra-high-Q toroid microcavity on a chip. Nature, 421:925–928, Feb 2003.
 +
* codata2002: Peter J. Mohr, Barry N. Taylor, and David B. Newell. CODATA recommended values of the fundamental physical constants: 2002. Rev. Mod. Phys., 77, Jan 2005. Available online at http://physics.nist.gov/constants.
 +
* Dicke1954: R. H. Dicke. Coherence in spontaneous radiation processes. Phys. Rev., 93(1):99, Jan 1954.
 +
* Feynman1963: Richard Feynman, Robert B. Leighton, and Matthew L. Sands. The Feynman Lectures on Physics. Addison-Wesley, 1963. 3 volumes.
 +
* Flambaum2004: V. V. Flambaum, D. B. Leinweber, A. W. Thomas, and R. D. Young. Limits on variations of the quark masses, QCD scale, and fine structure constant. Phys. Rev. D, 69(11):115006, 2004.
 +
* Ramsey1949: Norman F. Ramsey. A new molecular beam resonance method. Phys. Rev., 76(7):996, Oct 1949.
 +
* Ramsey1950: Norman F. Ramsey. A molecular beam resonance method with separated oscillating fields. Phys. Rev., 78(6):695–699, Jun 1950.
 +
* Reinhold2006: E. Reinhold, R. Buning, U. Hollenstein, A. Ivanchik, P. Petitjean, and W. Ubachs. Indication of a cosmological variation of the proton-electron mass ratio based on laboratory measurement and reanalysis of h2 spectra. Phys. Rev. Lett., 96:151101, 2006.
 +
* Santarelli1999: G. Santarelli, Ph. Laurent, P. Lemonde, A. Clairon, A. G. Mann, S. Chang, A. N. Luiten, and C. Salomon. Quantum projection noise in an atomic fountain: A high-stability cesium frequency standard. Phys. Rev. Lett., 82:4619, 1999.
 +
* Uhlenbeck1926: G. E. Uhlenbeck and S. Goudsmit. Spinning electrons and the structure of spectra. Nature, 117(2938):264, Feb 1926.
 +
* Wineland1992: D. J. Wineland, J. J. Bollinger, W. M. Itano, F. L. Moore, and D. J. Heinzen. Spin squeezing and reduced quantum noise in spectroscopy. Phys. Rev. A, 46(11):R6797–R6800, Dec 1992.
 +
* Wineland1994: D. J. Wineland, J. J. Bollinger, W. M. Itano, and D. J. Heinzen. Squeezed atomic states and projection noise in spectroscopy. Phys. Rev. A, 50(1):67–88, Jul 1994.
 +
 
 +
== Notes ==
 +
 
 +
[[Category:8.421]]

Latest revision as of 02:46, 22 May 2020


Classical Resonances

Introduction

Classically, a resonance is a system where one or more variables change periodically such that when the system is no longer driven by an extended periodic process, the decay of the system's oscillation takes many (or at least several) oscillation periods. Equivalently, the response of the driven system as a function of drive frequency exhibits some form of peaked structure. The frequency corresponding to the maximum response of the system is called the resonance frequency ()

<figure id="fig:example_resonances">

Resonances-example-resonances.png

A resonance in the time (left) and frequency (right) domains. The time domain picture shows the (decaying) oscillation in some variable of the undriven system, while the frequency-domain pictures shows the steady-state response amplitude of the driven system. The time units are chosen such that while the quality factor is . </figure>

The simplest resonance systems have a single resonance frequency, corresponding to the harmonic motion of the variable. Some form of dissipation (damping) results in a finite damping time () for the undriven system, and a finite width () of the resonance curve for the driven system. The quantities and are related by a Fourier transformation: any oscillation with time-varying amplitude must be made up of a superposition of different frequency components, giving the resonance curve a finite width in frequency space. Low dissipation results in a long decay time , and a narrow frequency width . The ratio of frequency width to resonance frequency is called the quality factor .

Atomic physics often deals with isolated atomic systems in a vacuum, providing resonances of high quality factor . For example, an optical transition, even in a room-temperature (ie Doppler-broadened) gas, will have a -factor of

In contrast, high factors in solids typically require cryogenic temperatures: typical factors of mechanical or electrical systems are at room temperature and at temperatures.

High Q values are obtained in solids acting as optical resonators: has been achieved in the whispering gallery modes of spheres or cylinders of high-purity glass [1].

Resonances-whispering-gallery.png

One of the whispering-gallery resonators described in [1]. This particular resonator had a quality factor . The very high surface quality required for such low losses is achieved by having surface tension shape the rim of the disk after it has been temporarily liquefied by a laser pulse; the inset shows the resonator before this treatment.

At the macroscopic scale, astronomical systems consisting of massive bodies travelling essentially undisturbed through the near-vacuum of space can also exhibit high factors. The rotation of the earth has a value of , and pulsars of .

A resonance is particularly useful for science and technology if it is reproducible by different realizations of the same system, and if it has a well-understood theoretical connection to fundamental constants. In atomic physics, quantum mechanics ensures both features: atoms of the same species are fundamentally identical (although the probing apparatus is not), and the quantum mechanical description of atomic structure is well understood and highly accurate, at least for atoms with not too many electrons. The resonance frequencies of hydrogen, and to a lesser degree helium, are directly tied via quantum mechanics to fundamental constants such as the Rydberg constant, [2], or the fine structure constant [2]. In fact, the Rydberg constant is the most accurately known constant in all of physics, and most fundamental constants have been determined by atomic physics or optical techniques. Additional motivation for measuring fundamental constants with ever-increasing accuracy has been provided by the speculation (and claims of evidence for it [3][4]), that the fundamental constants may not be so constant after all, but that their value is tied to the evolution (and therefore the age) of the universe. Furthermore unexpected resonances, or splittings of resonances, have in the past indicated the need for new theories or modifications of theories. For instance, "anomalous" effects in the Zeeman structure (magnetic-field dependance) of atomic lines led to the discovery of spin [5]. while Lamb's measurement of the splitting between the and states of atomic hydrogen, on the order of 1000MHz instead of 0 as predicted by the Dirac theory, fostered the development of quantum electrodynamics, the quantum theory of light.


Classical Harmonic Oscillator

A classical harmonic oscillator (HO) is a system described by the second order differential equation

such as a mass on a spring, or a charge, voltage, or current in an electric RLC resonant circuit. For weak damping () the undriven system decays with an exponential envelope,

with . In the cases we will consider, so that . The decay rate constant for the amplitude is , while for the stored energy it is , i.e. the stored energy decays exponentially with a time constant . If the harmonic oscillator is driven at a frequency close to resonance, , the amplitude response is a lorentzian:

where is the detuning as shown on the right-hand side of <xr id="fig:example_resonances"/>. The full width at half maximum (FWHM) of a lorentzian curve is leading to a quality factor

Note that , , and are measured in angular frequency units \unit{\radian\per\second}, or \unit{\reciprocal\second} for short, and should not be confused with frequencies , etc. When quoting values, we will often write explicitly rather than to remind ourselves that the quantity in question is an angular frequency. We will never write : although formally dimensionally consistent, this invites confusion with real (laboratory or Hertzian) frequencies. For brevity, we will often write or say "frequency" when we mean angular frequency, but will quote real frequencies as . Note that the natural unit for decay rate constants is that of an angular frequency, as in . Therefore we will express decay rates as inverse times in angular frequency units: for instance, but not , nor . Damping time constants are the inverse of decay rate constants, .

Resonance Widths and Uncertainty Relations

From it follows that damping time and the resonance linewidth of the driven system obey: or, assuming , : a finite number of frequency components or energies () is necessary to synthesize a pulse of finite () width in time.

<figure id="fig:gated_pulse">

Resonances-gated-pulse.png

Measurement in a limited time , modelled as an ideal monochromatic sine wave of frequency gated by an observation window of finite width </figure>

This is quite similar to an uncertainty relation familiar from Fourier transformation theory, according to which the measurement of a frequency in a finite time (see <xr id="fig:gated_pulse"/>) results in a frequency spread obeying . By using we can further connect this with the usual Heisenberg uncertainty relation

Question: <definition id="q:classical_line_splitting" noautocaption noblock>(Q%i)</definition> Does the Heisenberg uncertainty relation , or rather the frequency uncertainty relation that follows from (classical) Fourier theory hold in classical systems? Can you measure the angular frequency of a classical harmonic oscillator in a time with an accuracy better than ?

Answer: Yes - if you have a good model for the signal, for instance if you know that it is a pure sine wave, and if the signal to noise ratio (SNR) of the measurement is good enough, then you can fit the sine wave's frequency to much better accuracy than its spectral width (see Fig. <xr id="fig:line_splitting"/>). As a general rule, the line center can be found to within an uncertainty . This is known as splitting the line. Splitting the line by a factor of 100 is fairly straightforward, splitting it by a factor of a 1000 is a real challenge. As an extreme example of this, Caesium fountain clocks interrogate a 9 GHz transition for a typical measurement time of 1 s, yielding , but the best ones can nonetheless achieve relative accuracies of [6]. Of course, this sort of performance requires a very good understanding of the line shape and of systematics.


<figure id="fig:line_splitting">

Resonances-line-splitting.png

Splitting the line in time and frequency domains. Given a sufficiently good model of the signal or line shape, and adequate signal-to-noise, one can find the center frequency of the underlying signal to much better than or the line width. </figure>

Question: <definition id="q:quantum_line_splitting" noautocaption noblock>(Q%i)</definition> Can you measure the angular frequency of a quantum mechanical harmonic oscillator in a time to better than ?

Question: <definition id="q:laser_line_splitting" noautocaption noblock>(Q%i)</definition> Can you measure the angular frequency of a laser pulse lasting a time to better than ?

If you answered <xr id="q:quantum_line_splitting"/> and <xr id="q:classical_line_splitting"/> differently, you may have a problem with <xr id="q:laser_line_splitting"/>. Is a laser pulse quantum or classical? Clearly it is possible to beat for a laser pulse. For instance, you can superimpose the laser pulse with a laser of fixed and known frequency on a photodiode, and fit the observed beat note. The stronger the probe pulse, the better the SNR of the beat note, and the more accurately you can extract the probe frequency. So how are we to reconcile quantum mechanics and classical mechanics, and what does the Heisenberg uncertainty really state?

The Heisenberg uncertainty relation makes a statement about predicting the outcome of a single measurement on a single system. For a single photon, the limit does indeed hold. However, nothing in quantum mechanics says that you cannot improve your knowledge about the average values of the quantities characterizing the system by repeated measurements on identical copies of it. In the laser example above, the frequency resolution improves with probe pulse strength because we are measuring many photons - for the purposes of this discussion we could have measured the frequencies of the photons sequentially.

For independent measurement of uncorrelated photons the SNR is given by : the signal grows as , while the noise is the shot noise of the photon number, which grows as . This SNR allows a frequency uncertainty of , known as the standard quantum limit. If we allow the use of entangled or correlated states of the photons, then the uncertainty can be as low as the Heisenberg limit [7][8].

Let us now revisit <xr id="q:quantum_line_splitting"/>. You may have heard that the quantum mechanical description of electromagnetism, quantum electrodynamics (QED), represents any single mode of the electromagnetic field by a harmonic oscillator of the same frequency. The ground state corresponds to no photons in the mode, the first excited state to one photon and so forth. This description is valid because photons to a very good approximation do not interact: the addition of a photon changes the system's energy always by the same increment. Since the many-photon pulse from <xr id="q:laser_line_splitting"/> maps onto a quantum harmonic oscillator, it seems to follow that <xr id="q:quantum_line_splitting"/> must also be answered in the affirmative.

On the other hand, a harmonic oscillator is a single quantum system to which the Heisenberg limit must apply. The resolution of this apparent contradiction is that <xr id="q:quantum_line_splitting"/> is asking about a measurement of the fundamental frequency of the harmonic oscillator, not the energy of a particular level. Therefore if you measure the energy of the n-th level to , which can be done by exciting the -th level from the ground state through a nonlinear process, then the uncertainty on the harmonic oscillator resonance frequency (that corresponds to the laser frequency in <xr id="q:quantum_line_splitting"/>) is given by .

If the interaction with the oscillator is restricted to classical fields or forces, then there is an additional uncertainty of on which particular level of the oscillator is being measured and so we recover the standard quantum limit mentioned previously.

Magnetic Resonance: The Classical Magnetic Moment in a Spatially Uniform Field

Harmonic oscillator versus two-level systems

Now, unlike in classical mechanics, most resonances studied in atomic physics are not harmonic oscillators, but two-level systems. Unlike harmonic oscillators, two-level systems show saturation. When a harmonic oscillator is driven longer or faster, higher and higher excited states are populated: the oscillator amplitude can become arbitrarily large. In contrast, the amplitude of oscillation in a two-level system is limited to one half in the appropriate dimensionless units.(An analogous dimensionless amplitude for the harmonic oscillator would be the amplitude measured in units of the oscillator ground state size.)

Why, and under what conditions, do classical harmonic oscillator models of a two-level system work? A two-level system of energy difference can be approximated by a harmonic oscillator of frequency when saturation effects in the two-level system are negligible, i.e. when the population of the second excited state in the harmonic oscillator problem is negligible, or equivalently when the population ratio of the first excited state to the the ground state is small: . This is the basis for the classical Lorentz model of the electron bound in the atom that describes many linear atomic properties (for instance the refractive index) very well. See "The origin of the refractive index" in chapter 31 of the Feynman Lectures on Physics [9].

When saturation comes into play, i.e. when the initial ground state is appreciably depleted, the harmonic oscillator ceases to be a good model. The limit on the oscillation amplitude in a two-level system suggests that a classical system with periodic evolution and a limit on the amplitude, namely rotation, could provide a better classical model of a two-level system. Indeed, the motion of a classical magnetic moment in a uniform field provides a model that captures almost all features of the quantum-mechanical two-level system, the exception being the projection onto one of the two possible outcomes in a measurement.

Magnetic Moment in a Static Field

The interaction energy of a magnetic moment with a magnetic field is given by

In a uniform field the force

vanishes, but the torque

does not. For an angular momentum the equation of motion is then <equation id="eq:classical_precession_in_static_field" noautocaption> (%i) </equation> where we have introduced the gyromagnetic ratio as the proportionality constant between angular momentum and magnetic moment, as shown in Figure <xr id="fig:static_precession"/>.

<figure id="fig:static_precession">

Resonances-static-precession.png

Precession of a the magnetic moment and associated angular momentum about a static field .

</figure>

This describes the precession of the magnetic moment about the magnetic field with angular frequency

is known as the Larmor frequency. For electrons we have , for protons .

Transformation to a Rotating Coordinate System

A vector rotating at constant angular velocity is described by

Then the rates of change of measured in a coordinate system rotating at and in an inertial system are related by

This follows immediately from the following facts:

  • If is constant in the rotating system then .
  • If then .
  • Coordinate rotation is a linear transformation.

This transformation is sometimes abbreviated as the schematic rule <equation id="eq:rot_frame_transformation" noautocaption> (%i) </equation> It follows that the angular momentum in a rotating frame obeys

If we choose , then is constant in the rotating frame. Often it is useful to think of a fictitious magnetic field that appears in a rotating frame.

Larmor's Theorem for a Charged Particle in a Magnetic Field

The vanishing of the torque on a magnetic moment when viewed in the correct rotating frame is reminiscent of Larmor's theorem for the motion of a charged particle in a magnetic field, which we now present.

According to answers.com, Lamor's theorem can be stated as

For a system of charged particles, all having the same ratio of charge to mass, moving in a central field of force, the motion in a uniform magnetic induction B is, to first order in B, the same as a possible motion in the absence of B except for the superposition of a common precession of angular frequency equal to the Larmor frequency.

This is also nicely discussed in the Feynman Lectures of Physics Vol. 2, 34-5 (https://www.feynmanlectures.caltech.edu/II_34.html).

If the Lorentz force acts in an inertial frame,

then in the rotating frame, according to the rule <xr id="eq:rot_frame_transformation"/> we have

resulting in a force in the rotating frame given by

where we have used . Choosing

yields

if the field is not too large. Thus the Lorentz force approximately disappears in the rotating frame.

Although Larmor's theorem is suggestive of the rotating co-ordinate transformation, it is important to realize that the two transformations, though identical in form, apply to fundamentally different systems. A magnetic moment is not necessarily charged- for example a neutral atom can have a net magnetic moment, and the neutron possesses a magnetic moment in spite of being neutral - and it experiences no net force in a uniform magnetic field. Furthermore, the rotating co-ordinate transformation is exact for a magnetic moment, whereas Larmor's theorem for the motion of a charged particle is only valid when the term is neglected.

Note: A breakdown of Larmor's theorem occurs for free electrons. Free electrons orbit in a magnetic field at the cyclotron frequency which is twice Larmor's frequency. The reason is that the orbiting velocity is now given by . As can be seen in the equation above, in this case, the centrifugal force equals minus one half of the Coriolis force, and therefore twice the frequency of the rotating frame is needed to cancel the effects of the applied magnetic field.

The reason why Larmor's theorem breaks down for free electrons is that the total velocity of the electron IS the rotational cyclotron motion. In contrast, in a composite system of positive and negative charges, you have Coulomb forces and orbital motion with high velocities, much higher than those due to the rotational motion.

Rotating Magnetic Field on Resonance

<figure id="fig:rotating_frame">

Resonances-rotating-frame.png

Field and moment vectors in the static and rotating frames for the case of resonant drive. </figure>

Consider a magnetic moment precessing about a field with in spherical coordinates, where (as shown in fig:rotating_frame/>). Assume that we now apply an additional field , in the -plane rotating at . To solve the resulting problem it is simplest to go into the rotating frame (fig:rotating_frame/>). Then is stationary, say along , and there is an additional fictitious field which cancels the field . So in the rotating frame we are left just with the static field , and the magnetic moment precesses about at the Rabi frequency

A magnetic moment initially along the axis will point along the axis at a time given by , while a magnetic moment parallel or antiparallel to the applied magnetic field does not precess in the rotating frame.

Question: <definition id="q:rabi_freq_blue_detuned" noautocaption noblock>(Q%i)</definition> Assume the magnetic moment is initially pointing along the axis. Assume that a rotating field is applied, but that it rotates at a frequency , where is the Larmor frequency for the static field . Compared to the on-resonant case, , is the oscillation frequency of the magnetic moment.

  • larger
  • the same
  • smaller

Question: Same question as <xr id="q:rabi_freq_blue_detuned"/> but for .

Rotating Magnetic Field Off-Resonance

If the rotation frequency of does not equal the Larmor frequency associated with the static field , then in the frame rotating with at frequency the static field is not completely cancelled by the fictitious field , but a difference along remains, giving rise to a total effective field in the rotating frame

The effective field is static, lies at an angle with the z

and is of magnitude

The magnetic moment precesses around it with an effective (sometimes called generalized) Rabi frequency

where is the Rabi frequency associated with , and is the detuning from resonance with the Larmor frequency .

Geometrical Solution for the Classical Magnetic Moment in Static and Rotating Fields

<figure id="fig:rotating_coord_construction">

Resonances-classical-rabi-construction.png

Geometrical relations for the spin in combined static and rotating magnetic fields, viewed in the frame co-rotating with the drive field . At lower right is a view looking straight down the axis.

</figure>

Referring to <xr id="fig:rotating_coord_construction"/>, we have

On the other hand

so that <equation id="eq:classical_rabi_flopping" noautocaption> (%i) </equation> With the Larmor frequency of the static field, the detuning, the resonant and the generalized Rabi frequencies. Note that the precession is faster, but the amplitude smaller for an off-resonant field than for the resonant case. The above result is also the correct quantum-mechanical result.

If we define the quantity , we obtain

In the quantum mechanical treatment (see below), is the probability to find the system in the second state, or the spin flip probability.

"Rapid" Adiabiatic Passage (Classical Treatment)

Rapid adiabatic passage is a technique for inverting a spin by (slowly) sweeping the detuning of a drive field through resonance. "Slowly" means slowly compared to the Larmor frequency about the effective static field in the rotating frame for all times ("Rapid" means fast compared to relaxation processes which we neglect here).

The physical picture is as follows. Assume the detuning is initially negative (, ). Since

the effective magnetic field initially points of a small angle relative to the axis. If the detuning is increased slowly compared to the Larmor frequency, the spin will continue to precess tightly around , which for points along the x axis, and for along the axis (see <xr id="fig:rapid_adiabatic_passage"/>).

<figure id="fig:rapid_adiabatic_passage">

Resonances-adiab.png

{Motion of the spin during rapid adiabatic passage, viewed in the frame rotating with . The spin's rapid precession locks it to the direction of and thus it is dragged through an angle as the frequency is swept through resonance. </figure>

Thus the magnetic moment, starting out along , ends up pointing along . Note that in the rotating frame remains always (almost) parallel to the effective field . A similar precess is used in magnetic traps for atoms, but there is a real, spatially dependent field constant in time. As the atom moves in this field, the fast precession of the magnetic moment about the local field keeps its direction locked to the local field, whose direction varies in the lab frame. Returning to rapid adiabatic passage, since the generalized Rabi frequency is smallest and equal to the resonant Rabi frequency at , the adiabatic requirement is most severe there, i.e. near . Near we have, with ,

where the exclamation point in indicates a requirement which we impose. Consequently, if the evolution is to be adiabatic, we must have . This means that the change of rotation frequency per Rabi period , , must be small compared to the Rabi frequency .

Note that the inversion of the spin is independent of whether is swept up or down through the resonance.

Quantized Spin in a Magnetic Field

Equation of Motion for the Expectation Value

For the system we have been considering, the Hamiltonian is

Recalling the Heisenberg equation of motion for any operator is

where the last term refers to operators with an explicit time dependence, we have in this instance

Using with the Levi-Civita symbol , we have

or in short

These are just like the classical equations of motion <xr id="eq:classical_precession_in_static_field"/>, but here they describe the precession of the operator for the magnetic moment or for the angular momentum about the magnetic field at the (Larmor) angular frequency .

Note that:

  • Just as in the classical model, these operator equations are exact; we have not neglected any higher order terms.
  • Since the equations of motion hold for the operator, they must hold for the expectation value
  • We have not made use of any special relations for a spin- system, but just the general commutation relation for angular momentum. Therefore the result, precession about the magnetic field at the Larmor frequency, remains true for any value of angular momentum .
  • A spin- system has two energy levels, and the two-level problem with coupling between two levels can be mapped onto the problem for a spin in a magnetic field, for which we have developed a good classical intuition.
  • If coupling between two or more angular momenta or spins within an atom results in an angular momentum , the time evolution of this angular momentum in an external field is governed by the same physics as for the two-level system. This is true as long as the applied magnetic field is not large enough to break the coupling between the angular momenta; a situation known as the Zeeman regime. Note that if the coupled angular momenta have different gyromagnetic ratios, the gyromagnetic ratio for the composite angular momentum is different from those of the constituents.
  • For large magnetic field the interaction of the individual constituents with the magnetic field dominates, and they precess separately about the magnetic field. This is the Paschen-Back regime.
  • An even more interesting composite angular momentum arises when two-level atoms are coupled symmetrically to an external field. In this case we have an effective angular momentum for the symmetric coupling:
Resonances-Dicke-states.png

Level structure diagram for two-level atoms in a basis of symmetric states [10]. The leftmost column corresponds to an effective spin- object. Other columns correspond to manifolds of symmetric states of the atoms with lower total effective angular momentum.

Again the equation of motion for the composite angular momentum is a precession. This is the problem considered in Dicke's famous paper [10], in which he shows that this collective precession can give rise to massively enhanced couplings to external fields ("superradiance") due to constructive interference between the individual atoms.

The Two-Level System: Spin-1/2

Let us now specialize to the two-level system and calculate the time evolution of the occupation probabilities for the two levels.

<figure id="fig:two_level_spin_half">

Resonances-two-level.png

Equivalence of two-level system with spin-. Note that for the spin-up state (spin aligned with field) is the ground state. For an electron, with , spin-up is the excited state. Be careful, as both conventions are used in the literature. </figure>

We have that

where in the last equation we have used the fact that . The signs are chosen for a spin with , such as a proton (Figure <xr id="fig:two_level_spin_half"/>). For an electron, or any other spin with , the analysis would be the same but for the opposite sign of and the corresponding exchange of and . If the system is initially in the ground state, (or the spin along , ), the expectation value obeys the classical equation of motion <xr id="eq:classical_rabi_flopping"/>: <equation id="eq:rabi_transition_probability" noautocaption> (%i) </equation>

Equation <xr id="eq:rabi_transition_probability"/> is the probability to find system in the excited state at time if it was in ground state at time . <xr id="fig:rabi_signal"/> shows a real-world example of such an oscillation.

<figure id="fig:rabi_signal">

Resonances-Rabi.png

Rabi oscillation signal taken in the Vuleti\'{c} lab shortly after this topic was covered in lecture in 2008. The amplitude of the oscillations decays with time due to spatial variations in the strength of the drive field (and hence of the Rabi frequency), so that the different atoms drift out of phase with each other. </figure>

Matrix form of Hamiltonian

With the matrix representation

we can write the Hamiltonian associated with the static field as

where is the Larmor frequency (recall that is negative for an electron, making positive), and

is a Pauli spin matrix. The eigenstates are , with eigenenergies . A spin initially along , corresponding to

evolves in time as

which describes a precession with angluar frequency . The field , rotating at in the plane corresponds to

where have used the Pauli spin matrices , . The full Hamiltonian is thus given by

<equation id="eq:dressed_atom_hamiltonian" noautocaption>

(%i) </equation> This is the famous "dressed atom" Hamiltonian in the so-called "rotating wave approximation". However, note that in the treatment here there are no approximations; it is exact. Its eigenstates and eigenvalues provide a very elegant, very intuitive solution to the two-state problem.

Solution of the Schrodinger Equation for Spin-1/2 in the Rotating Frame

The time-dependence of the above Hamiltonian can be eliminated by applying a unitary transformation to the system. Namely, a rotation about the z-axis accomplishes this. Call this rotation operator , which can be expressed

where we let . Then the transformed Hamiltonian

is

where . This time-independent Hamiltonian can be diagonalized exactly to obtain the eigenenergies and eigenstates. The general solution has the form,

In particular, the case and leads to the probability of finding the atom in the excited state to be

where is the generalized Rabi frequency. This form is identical to the one obtained in the classical picture.

Solution of the Schrodinger Equation for Spin-1/2 in the Interaction Representation

The same system can be solved by a more brute-force method by isolating the "bare" time-dependence first and then using substitutions. The interaction representation consists of expanding the state in terms of the eigenstates , of the Hamiltonian , including their known time dependence due to . That means we write here

Substituting this into the Schrodinger equation

then results in the equations of motion for the coefficients

Where we have used the matrix form of the Hamiltonian, <xr id="eq:dressed_atom_hamiltonian"/>. Introducing the detuning , we have

The explicit time dependence can be eliminated by the substitution

As you will show (or have shown) in the problem set, this leads to solutions for given by

with two constants that are determined by the initial conditions. For we find

as already derived from the fact that the expectation value for the magnetic moment obeys the classical equation.

"Rapid" Adiabiatic Passage (Quantum Treatment)

Quantum mechanically, we have seen that the Hamiltonian of an interacting two-level system can be written as

where . Let us call the "bare" i.e. unperturbed, eigenstates of the Hamiltonian as and . If you examine the eigenstates of this Hamiltonian, you will realize that by changing the frequency of your coupling, the eigenstates will "evolve" from e.g. to , or vice versa. This can be accomplished by sweeping at a rate . This leads to the Landau-Zener problem of a sweep through an avoided crossing.

Landau-zener-new.PNG

An avoided crossing. A system on one level can jump to the other if the parameter that governs the energy levels is swept sufficiently rapidly.

Whether or not the system follows an energy level adiabatically depends on how rapidly the energy is changed, compared to the minimum energy separation. To cast the problem in quantum mechanical terms, imagine two non-interacting states whose energy separation, , depends on some parameter which varies linearly in time, and vanishes for some value . Now add a perturbation having an off-diagonal matrix element which is independent of , so that the energies at are . The probability that the system will "jump" from one adiabatic level to the other after passing through the "avoided crossing" (i.e., the probability of non-adiabatic behavior) is

where

and . This result was originally obtained by Landau and Zener. The jumping of a system as it travels across an avoided crossing is called the Landau-Zener effect. Inserting the parameters for our magnetic field problem, we have

Note that when is satisfied, the probability of non-adiabatic behavior is exponentially small. This agrees with our classical analysis.

Let us now consider a diabatic sweep, where the probability to make a transition across the crossing is non-negligible, but small. This process can be described by the Schroedinger equation in a coherent way. In particular,

where is the effective sweep duration, or the dephasing time . This is determined by

where . This then gives us . Then we get

Note that the sum of the probability to undergo a transition and the probability to not undergo a transition must equal one. This means . Using our expression for we obtained above, we find

Therefore we've determined the probability to undergo a diabatic transition two different ways and see that they agree.

Incidentally the "rapid" in adiabatic rapid passage is something of a misnomer. The technique was originally developed in nuclear magnetic resonance in which thermal relaxation effects destroy the spin polarization if one does not invert the population sufficiently rapidly. In the absence of such relaxation processes one can take as long as one pleases to traverse the anticrossings, and the slower the crossing the less the probability of jumping.

Decoherence Processes, Mixed States, Density Matrices

The purely Hamiltonian evolution described by the Schrodinger Equation leaves the system in a pure state. However, often we have to deal with incoherent processes such as the uncontrolled loss or addition of atoms, or other perturbations that change the system evolution in an uncontrollable way. If the incoherent process is merely a (state-dependent) loss of atoms to a third state then we can describe the system by a Hamiltonian with complex eigenstates

The decay of the norm corresponds to decay out of the , system, as in <xr id="fig:decay_out"/>.

<figure id="fig:decay_out">

Resonances-decay-out.png

Decay out of the system, which can be modelled by a non-Hermitian Hamiltonian, the imaginary part of the eigenvalue corresponding to a decay rate. </figure>

However, other processes, such as spontaneous decay from to or loss of coherence (well-defined phase relationship) between and due to uncontrolled level shifts (e.g. collisions, uncontrolled B-field fluctuations) cannot be dealt with within the Hamiltonian approach and require the density matrix formalism.

Density Operator

The density operator formalism is necessary when the preparation process does not prepare a single quantum state , but a statistical mixture of quantum states with probabilities . The density operator is the projection operator for that statistical mixture, or ensemble average.

From the Schrodinger equation it follows that the Hamiltonian evolution of the density operator is governed by

In the presence of damping and decay processes there are additional terms, and the time evolution is governed by a so-called Master equation. The expectation value of any operator is given by

The expectation value of the unity operator must be 1, so The expectation value of , , is unity for a pure state , and for a mixed state. In any basis , is specified in terms of its matrix elements

and the expectation value of any operator can be written as

The diagonal elements of the density matrix () are called the probabilities since is the probability to find the system in state , while the off-diagonal elements are called coherences ( is the coherence between states and ). If we write with , real then is the phase between states and , while . The coherence is maximum when . Finally note that the density operator is hermitian, so that , as we would expect for a meaningfully-defined coherence between two states.

Density Matrix for a Two-Level System and Bloch Vector

We now introduce a slightly different parametrization of the two-level Hamiltonian <xr id="eq:dressed_atom_hamiltonian"/> and of the corresponding density matrix:

In the problem set you will show (or have shown) that the Hamiltonian evolution of the density matrix

implies the equation of motion

for the vectors and This slightly generalizes our previous result: for a pure state using the Heisenberg equations of motion we had shown that the spin- and the corresponding magnetic moment obey

but we have now generalized this result to mixed states, i.e. to ensemble averages that have less than the maximum possible magnetic moment.

We have just derived the theorem by Feynman, Vernon and Hellwarth (1957) which states that the time evolution of the density matrix for the most general two-level system is isomorphic to the behavior of a classical moment in a suitable time-dependent magnetic field.

Note that Hamiltonian evolution does not change the purity of a state: a pure state always remains pure, no matter how violently it is rotated, and a mixed state retains its degree of mixedness () Here we can check this explicitly by noting that

Since , the length of does not change, and hence is constant in time.

Phenomenological Treatment of Relaxation: Bloch Equations

Statistical mechanics tells us the form which the density matrix will ultimately take, but it does not tell us how the system will get there or how long it will take. All we know is that ultimately the density matrix will thermalize to

where Z is the partition function.

Since the interactions which ultimately bring thermal equilibrium are incoherent processes, the density matrix formulation seems like a natural way to treat them. Unfortunately in most cases these interactions are sufficiently complex that this is done phenomenologically. For example, the equation of motion for the density matrix might be modified by the addition of a damping term:

which would (in the absence of a source of non-equilibrium interactions) drive the system to equilibrium with time constant .

This equation is not sufficiently general to describe the behavior of most systems studied in resonance physics, which exhibit different decay times for the energy and phase coherence, called and respectively.

  • - decay time for population differences between non-degenerate levels, e.g. for (also called the energy decay time).
  • - decay time for coherences (between either degenerate or non-degenerate states), i.e. for or .

The reason is that, in general, it requires a weaker interaction to destroy coherence (the relative phase of the coefficients of different states) than to destroy the population difference, so some relaxation processes will relax only the phase, resulting in . (caution: certain types of collisions violate this generality.)

The effects of thermal relaxation with the two decay times described above are easily incorporated into the vector model for the 2-level system since the z-component of the population vector represents the population difference and and represent coherences (i.e. off-diagonal matrix elements of ): The results are

For a magnetic spin system corresponds directly to the magnetic moment . The above equations were first introduced by Bloch in this context and are known as the Bloch equations.

The addition of phenomenological decay times does not generalize the density matrix enough to cover situations where atoms (possibly state-selected) are added or lost to a system. This situation can be covered by the addition of further terms to . Thus a calculation on a resonance experiment in which state-selected atoms are added to a two-level system through a tube which also permits atoms to leave (e.g. a hydrogen maser) might look like

where R is the rate of addition of state-selected atoms. The last two terms express effects of atom escape from the system and of collisions (e.g. spin exchange) that can't easily be incorporated in and .

The terms representing addition or loss of atoms will not have zero trace, and consequently will not maintain Tr. Physically this is reasonable for systems which gain or lose atoms; the application of the density matrix to this case shows its power to deal with complicated situations. In most applications of the above equation, one looks for a steady state solution (with ), so this does not cause problems.

References

  • Armani2003: D. K. Armani, T. J. Kippenberg, S. M. Spillane, and K. J. Vahala. Ultra-high-Q toroid microcavity on a chip. Nature, 421:925–928, Feb 2003.
  • codata2002: Peter J. Mohr, Barry N. Taylor, and David B. Newell. CODATA recommended values of the fundamental physical constants: 2002. Rev. Mod. Phys., 77, Jan 2005. Available online at http://physics.nist.gov/constants.
  • Dicke1954: R. H. Dicke. Coherence in spontaneous radiation processes. Phys. Rev., 93(1):99, Jan 1954.
  • Feynman1963: Richard Feynman, Robert B. Leighton, and Matthew L. Sands. The Feynman Lectures on Physics. Addison-Wesley, 1963. 3 volumes.
  • Flambaum2004: V. V. Flambaum, D. B. Leinweber, A. W. Thomas, and R. D. Young. Limits on variations of the quark masses, QCD scale, and fine structure constant. Phys. Rev. D, 69(11):115006, 2004.
  • Ramsey1949: Norman F. Ramsey. A new molecular beam resonance method. Phys. Rev., 76(7):996, Oct 1949.
  • Ramsey1950: Norman F. Ramsey. A molecular beam resonance method with separated oscillating fields. Phys. Rev., 78(6):695–699, Jun 1950.
  • Reinhold2006: E. Reinhold, R. Buning, U. Hollenstein, A. Ivanchik, P. Petitjean, and W. Ubachs. Indication of a cosmological variation of the proton-electron mass ratio based on laboratory measurement and reanalysis of h2 spectra. Phys. Rev. Lett., 96:151101, 2006.
  • Santarelli1999: G. Santarelli, Ph. Laurent, P. Lemonde, A. Clairon, A. G. Mann, S. Chang, A. N. Luiten, and C. Salomon. Quantum projection noise in an atomic fountain: A high-stability cesium frequency standard. Phys. Rev. Lett., 82:4619, 1999.
  • Uhlenbeck1926: G. E. Uhlenbeck and S. Goudsmit. Spinning electrons and the structure of spectra. Nature, 117(2938):264, Feb 1926.
  • Wineland1992: D. J. Wineland, J. J. Bollinger, W. M. Itano, F. L. Moore, and D. J. Heinzen. Spin squeezing and reduced quantum noise in spectroscopy. Phys. Rev. A, 46(11):R6797–R6800, Dec 1992.
  • Wineland1994: D. J. Wineland, J. J. Bollinger, W. M. Itano, and D. J. Heinzen. Squeezed atomic states and projection noise in spectroscopy. Phys. Rev. A, 50(1):67–88, Jul 1994.

Notes

  1. 1.0 1.1 D. K. Armani, T. J. Kippenberg, S. M. Spillane, and K. J. Vahala. Ultra-high-Q toroid microcavity on a chip. Nature, 421:925–928, Feb 2003.
  2. 2.0 2.1 Peter J. Mohr, Barry N. Taylor, and David B. Newell. CODATA recommended values of the fundamental physical constants: 2002. Rev. Mod. Phys., 77, Jan 2005. Available online at http://physics.nist.gov/constants.
  3. V. V. Flambaum, D. B. Leinweber, A. W. Thomas, and R. D. Young. Limits on variations of the quark masses, QCD scale, and fine structure constant. Phys. Rev. D, 69(11):115006, 2004.
  4. E. Reinhold, R. Buning, U. Hollenstein, A. Ivanchik, P. Petitjean, and W. Ubachs. Indication of a cosmological variation of the proton-electron mass ratio based on laboratory measurement and reanalysis of h2 spectra. Phys. Rev. Lett., 96:151101, 2006.
  5. G. E. Uhlenbeck and S. Goudsmit. Spinning electrons and the structure of spectra. Nature, 117(2938):264, Feb 1926.
  6. G. Santarelli, Ph. Laurent, P. Lemonde, A. Clairon, A. G. Mann, S. Chang, A. N. Luiten, and C. Salomon. Quantum projection noise in an atomic fountain: A high-stability cesium frequency standard. Phys. Rev. Lett., 82:4619, 1999.
  7. D. J. Wineland, J. J. Bollinger, W. M. Itano, F. L. Moore, and D. J. Heinzen. Spin squeezing and reduced quantum noise in spectroscopy. Phys. Rev. A, 46(11):R6797–R6800, Dec 1992.
  8. D. J. Wineland, J. J. Bollinger, W. M. Itano, and D. J. Heinzen. Squeezed atomic states and projection noise in spectroscopy. Phys. Rev. A, 50(1):67–88, Jul 1994.
  9. Richard Feynman, Robert B. Leighton, and Matthew L. Sands. The Feynman Lectures on Physics. Addison-Wesley, 1963. 3 volumes.
  10. 10.0 10.1 R. H. Dicke. Coherence in spontaneous radiation processes. Phys. Rev., 93(1):99, Jan 1954.