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| which meets the Heisenberg limit. | | which meets the Heisenberg limit. |
| === Squeezed light interferometry === | | === Squeezed light interferometry === |
− | Heisenberg-limited interferometry can also be accomplished using a
| + | |
− | variety of states of light, including squeezed states we studied in
| + | {{#lst:Squeezed light interferometry|content}} |
− | Section~2.2. Let us explore three configurations here.
| + | |
− | Vacuum squeezed state input. Because squeezed states can move
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− | noise between the <math>x</math> and <math>p</math> quadratures, it is intuitively
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− | reasonable that a state with low phase noise could be used to provide
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− | more accurate measurements of <math>\phi</math> than is possible with a coherent
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− | state, which has equal noise in the two quadratures.
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− | It might seem counter-intuitive, however, that we can get to the
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− | Heisenberg limit by replacing not the coherent state input, but
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− | rather, the vacuum state, in the Mach-Zehnder interferometer. This
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− | works because at the balanced operating point, the noise in the output
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− | is due to fluctuations entering in at the vacuum port. Before, we
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− | used <math>|\alpha{\rangle}|0{\rangle}</math> as input. Let us now replace this by
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− | :<math> | |
− | |\psi_{in} = |\alpha \rangle |0_r{\rangle}
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− | \,,
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− | </math>
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− | where <math>|0_r \rangle = S(r)|0{\rangle}</math> is a squeezed vacuum state. Recall that for
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− | the balanced interferometer, the final uncertainty in the phase
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− | measurement is
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− | :<math>
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− | {\langle}\Delta\phi \rangle = \frac{\sqrt{{\langle}\Delta Y^2{\rangle}}}{| \langle X{\rangle}|}
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− | \,,
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− | </math>
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− | where <math>X = a^\dagger a - b^\dagger b </math>, and <math>Y = a^\dagger b+ b^\dagger a</math>. For the squeezed
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− | vacuum + coherent state input, we find
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− | :<math>\begin{array}{rcl}
| |
− | \langle X \rangle &=& {\langle}\alpha| a^\dagger a |\alpha \rangle - \langle 0_r| b^\dagger b |0_r \rangle \approx
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− | |\alpha|^2 = n
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− | \\
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− | \langle Y \rangle &\approx& 0
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− | \\
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− | \langle Y^2 \rangle &\approx& |\alpha^2| \langle 0_r|(b+ b^\dagger )^2|0_r{\rangle}
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− | = |\alpha^2| e^{-r}
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− | \,.
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− | \end{array}</math>
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− | Thus, the uncertainty in the phase measurement is approximately
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− | :<math>
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− | {\langle}\Delta\phi \rangle \approx \frac{e^{-r/2}}{\sqrt{n}}
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− | \,.
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− | </math>
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− | In the limit of large squeezing, ie <math>r\rightarrow\infty</math>, the squeezed
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− | vacuum has nonzero average photon number, <math> \langle 0_r| b^\dagger b |0_r \rangle \sim
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− | \sinh^2 r = n_b</math>, so this expression does not vanish to zero. Rather, there
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− | is an optimal amount of squeezing, at which point the minimum phase
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− | uncertainty goes as <math>{\langle}\Delta\phi_{min} \rangle \sim 1/(n+n_b)</math>, which is
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− | close to the Heisenberg limit. See Caves, {\em Quantum-mechanical
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− | noise in an interferometer,} Phys. Rev. D, vol~23, p.~1693, 1981, for
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− | more on this subject.
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− | Yurke state input. The Heisenberg limit can also be reached
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− | using the Mach-Zehnder interferometer by replacing the input light
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− | states with this unusual squeezed state
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− | :<math>
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− | |\psi_{in} \rangle = \frac{1}{\sqrt{2}} \left[ { |n-1{\rangle}|n \rangle +
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− | |n{\rangle}|n-1 \rangle } \right]
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− | \,.
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− | </math>
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− | This is known as the Yurke state. It happens to be balanced
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− | already, and thus instead of operating our interferometer at
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− | <math>\phi=\pi/2</math>, we operate it at <math>\phi=0</math>, such that the output
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− | measurement gives <math>M=X</math>, and <math>\partial M/\partial \phi= Y</math>, and the
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− | final uncertainty in the phase measurement is
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− | :<math>
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− | {\langle}\Delta\phi \rangle = \frac{\sqrt{{\langle}\Delta X^2{\rangle}}}{| \langle Y{\rangle}|}
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− | \,.
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− | </math>
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− | For the Yurke state,
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− | :<math>\begin{array}{rcl}
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− | ( a^\dagger b + b^\dagger a) |n-1,n \rangle &=& \sqrt{n} \sqrt{n} |n{\rangle}|n-1{\rangle}
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− | + \sqrt{n-1}\sqrt{n+1} |n-2{\rangle}|n+1{\rangle}
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− | \\
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− | ( a^\dagger b + b^\dagger a) |n,n-1 \rangle &=& n |n-1{\rangle}|n{\rangle}
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− | + \sqrt{(n-1)(n+1)} |n+1{\rangle}|n-2{\rangle}
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− | \,.
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− | \end{array}</math>
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− | In calculating <math> \langle Y{\rangle}</math>, the terms with <math>|n-2{\rangle}</math> drop out, leaving us with
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− | :<math>\begin{array}{rcl}
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− | \langle Y \rangle = \frac{ \langle n,n-1|Y|n-1,n \rangle + \langle n-1,n|Y|n,n-1{\rangle}}{2} = n
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− | \,.
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− | \end{array}</math>
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− | Similarly, it is straightforward to show that
| |
− | :<math>\begin{array}{rcl}
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− | \langle X \rangle &=& 0
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− | \\
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− | \langle X^2 \rangle &=& \langle n_a^2 - 2n_an_b + n_b^2 \rangle = 2
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− | \,.
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− | \end{array}</math>
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− | Thus, the uncertainty in <math>\phi</math> is
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− | :<math>
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− | {\langle}\Delta\phi \rangle = \frac{\sqrt{2}}{n}
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− | \,,
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− | </math>
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− | which is (up to a factor of two) the Heisenber limit.
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− | Given how useful the Yurke state could be for interferometry, it is
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− | meaningful to consider how such a state might be made. One
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− | interesting proposal starts with two Bose-Einstien condenstates,
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− | prepared in a state of definite atom number, which we may model as two
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− | number eigenstates <math>|n{\rangle}|n{\rangle}</math>. The two condensates are weakly linked
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− | through a tunnel, which we may model as a beamsplitter, and detectors
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− | are placed to look for a single atom at the outputs. This is sketched
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− | below:
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− | ::[[Image:chapter2-quantum-light-part-5-interferometry-l7-yurke-state-bec.png|thumb|408px|none|]]
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− | If the top detector clicks, then one atom has left the condensates;
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− | however, it is unknown from which it came. The post-measurement
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− | state, after this single click, is thus
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− | :<math>\begin{array}{rcl}
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− | |\psi \rangle &=& \frac{a+b}{\sqrt{2}} |n{\rangle}|n{\rangle}
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− | \\
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− | &=& \sqrt{n} |n-1{\rangle}|n \rangle + \sqrt{n}|n{\rangle}|n-1{\rangle}
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− | \,,
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− | \end{array}</math>
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− | written unnormalized. Normalized, the proper post-measurement state
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− | is
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− | :<math>
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− | |\psi \rangle = \frac{|n-1{\rangle}|n \rangle + \sqrt{n}|n{\rangle}|n-1{\rangle}}{\sqrt{2}}
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− | \,.
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− | </math>
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− | This is the Yurke state. If the bottom detector had clicked instead,
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− | we would have obtained <math>|n-1{\rangle}|n{\rangle}-|n{\rangle}|n-1{\rangle}</math> instead, which is also
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− | useful. Similar techniques, involving beamsplitter mixed detection of
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− | spontaneous emission, can be used to entangle atoms (as we shall see
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− | later). More about this BEC entanglement method can be found in the
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− | literature; see, for example, Castin & Dalibard, Phys. Rev. A
| |
− | vol.~55, p.~4330, 1997, for the proposal to create Yurke states;
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− | Vogels, Chin, and Ketterle, Phys. Rev. Lett., vol.~90, p.~030403, 2003,
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− | for an experiment in which a squeezed BEC state was generated, and
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− | Bouyer and Kasevitch, Phys. Rev. A, vol.~56, p.~R1083, 1997, for a
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− | proposal to do Heisenberg limited spectroscopy with BECs.
| |
| === Sensitivity to loss === | | === Sensitivity to loss === |
| Entangled states, while very useful for a wide variety of tasks, | | Entangled states, while very useful for a wide variety of tasks, |
Quantum states and dynamics of photons
Interferometry and metrology
Suppose you are given a phase shifter of unknown :
\noindent
How accurately can you determine , given a certain time, and
laser power?
In this section, we consider this basic measurement problem, and show
how the usual shot noise limit can be exceeded by using quantum states
of light, reaching a quantum limit determined by Heisenberg's
uncertainty principle. This limit is achieved using entanglement,
which can be realized using entangled multi-mode photons, or by a
variety of squeezed states. The physics behind such quantum
measurement techniques generalizes to a wide range of metrology
problems, but a common challenge the need to reduce loss.
Shot noise limit
The Poisson distribution of photon number in coherent (laser) light
contributes an uncertainty of to optical
measurements. It is therefore reasonable to anticipate that with
photons, the uncertainty with which an unknown phase
can be determined might be bounded below by , based on the heuristic that . Such a limit is known as being due to shot noise, arising
from the particle nature of photons, as we shall now see rigorously.
Consider a Mach-Zehnder interferometer constructed from two 50/50
beamsplitters, used to measure :
\noindent
Let us analyze this interferometer, first by using a traditional
quantum optics approach in the Heisenberg picture, and second by using
single photons in the Schrodinger picture.
Previously, we've defined the unitary transform for a quantum
beamsplitter as being a rotation about the axis, so as to
avoid having to keep track of factors of . For variety, let's now
use a different definition; nothing essential will change.
Let the 50/50 beamsplitter transformation be
This acts on to produce operators describing the output of
the beamsplitter; in particular,
Similarly, the phase shifter acting on the mode operators performs
The Mach-Zehnder transform is thus
The way we have defined these transformations here, the output modes
of the interferometer, and , are
We are interested in the difference between the photon numbers
measured at the two outputs, , where the
extra factor of two is introduced for convenience. We find
The measurement result is thus
Define , and . Recognizing that
is the difference in photon number between the two output arms,
and recalling that this is the main observable result from changing
, we identify the signal we wish to see as being . Ideally,
the output signal should go as . The signal due to goes
as , and we shall see that this is the noise on the signal.
The average output signal , as a function of , looks like this:
\noindent
Note that if our goal is to maximize measurement sensitivity to
changes in , then the best point to operate the interferometer
at is around , since the slope is largest
there. At this operating point, if the interferometer's inputs have
laser light coming into only one port, then the outputs have equal
intensity; thus, the interferometer is sometimes said to be
"balanced" when .
What is the uncertainty in our measurement of , derived from the
observable ? By propagating uncertainties, this is
where
Let , such that , and .
For a coherent state input, , we find
if we define as the input state mean photon number.
Also,
This is consitent with our intuition: the signal should go as , and the undesired term goes as , so it is good that is small on
average. However, there are nontrivial fluctuations in , because
and is nonzero for the
coherent state! Specifically, the noise in is
and thus the variance in the measurement result is
From Eq.(\ref{eq:l7-dphi}), it follows that the uncertainty in
is therefore
This is a very reasonable result; as the number of photons used
increases, the accuracy with which can be determined increases
with . The improvement arises because greater laser power
allows better distinction between the signals in and .
Another way to arrive at the same result, using single photons, gives
an alternate interpretation and different insight into the physics.
As we have seen previously, acting on the ,
"dual-rail" photon state, a 50/50 beamsplitter performs a
rotation, and a phase shifter performs a
rotation. The Mach-Zehnder interferometer we're using can thus be
expressed as this transform on a single qubit:
\noindent
where the probability of measuring a single photon at the output is
. Walking through this optical circuit, the states are found to be
such that
Repeating this times (so that we use the same average number of
photons as in the coherent state case), we find that the standard
deviation in is
Given this, the uncertainty in is
This is the same uncertainty as we obtained for the coherent state
input, but the physical origin is different. Now, we see the noise as
being due to statistical fluctuations of a Bernoulli point process,
one event at a time. The noise thus comes from the amount
of time the signal is integrated over (assuming a constant rate of
photons). The noise is simply shot noise.
Heisenberg limit: entanglement
The shot noise limit we have just seen, however, is not fundamental.
Here is a simple argument that something better should be possible.
Recall that the desired signal at the output of our Mach-Zehnder
interferometer is , and the noise is .
If the inputs have and , and if were zero, then
the measured signal would be . And at the balanced
operating point ,
Thus, if the smallest photon number change resolvable is ,
then , from which it follows that
This is known as the "Heisenberg limit" on interferometry. There
are some general proofs in the literature that such a limit is the
best possible on interferometry. It governs more than just
measurements of phase shifters; gyroscopes, mass measurements, and
displacement measurements all use interferometers, and obey a
Heisenberg limit.
The argument above only outlines a sketch for why might be an
achievable limt, versus ; it assumes that the noise
can be made zero, however, and does not provide a means for
accomplishing this in practice.
Many ways to reach the Heisenberg limit in interferometry are now
known. Given the basic structure of a Mach-Zehnder interferometer,
\noindent
one can consider changing the input state , changing the
beamsplitters, or changing the measurement.
Common to all of these approaches is the use of entangled states. How
entanglement makes Heisenber-limited interferometry possible can be
demonstrated by the following setup. Let us replace the beamsplitters
in the Mach-Zehnder interferometer with entangling and dis-entangling
devices:
\noindent
Conceptually, the unusual beamsplitters may be the nonlinear
Mach-Zehnder interferometers we discussed in Section~2.3. They may
also be described by simple quantum circuits, using the Hadamard and
controlled-{\sc not} gate; for two qubits, the circuit is
\noindent
Note how the output is one of the Bell states. For three qubits, the
circuit is
\noindent
This output state, (suppressing normalization) is
known as a GHZ (Greenberger-Horne-Zeilinger) state. Straightforward
generalization leads to larger "Schrodinger cat" states
, using one Hadamard gate and
controlled-{\sc not} gates. Note that the reversed circuit
unentangles the cat states to produce computational basis states.
The important feature of such -qubit cat states, for our purpose,
is how they are transformed by phase shifters. A single qubit
becomes . Similarly, two entangled
qubits in the state , when sent through two phase
shifters, becomes , since the phases add. And
qubits in the state sent through
phase shifters becomes .
When such a phase shifted state is un-entangled, using the reverse of
the entangling circuit, the controlled-{\sc not} gates leave the
state , where the last
qubits are left in , and the first qubit (the qubit used as the
control for the {\sc cnot} gates) is
Compare this state with that obtained from the single qubit
interferometer, Eq.(\ref{eq:l7-1qubitphase}); instead of a phase
, the qubit now carries the phase . This means that the
probability of measuring a single photon at the output becomes
The standard deviation, from repeating this experiment, on average,
would be
Using , we obtain for the uncertainty in ,
which meets the Heisenberg limit.
Squeezed light interferometry
{{#lst:Squeezed light interferometry|content}}
Sensitivity to loss
Entangled states, while very useful for a wide variety of tasks,
including interferometry and metrology, are unfortunately generally
very fragile. In particular, entangled photon states degrade
quickly with due to loss.
Consider, for example, the two-qubit state (suppressing
normalization). If one of theses photons goes through a
mostly-transmitting beamsplitter, then the photon may be lost; let us
say this happens with probability . If a photon is lost,
the state collapses into one with one remaining photon, say .
This is a product state -- no longer entangled. It is not even a
superposition. No photon is lost with probability .
Even worse, if both modes suffer potential loss of a photon, then
no matter whcih mode looses a photon, the entangled state collapses;
this happens even if just one photon is lost. Thus, the
state retains some entanglement only with probability
.
And worst of all, if we have an -photon cat state
, and all modes are subject to loss
, then useful entanglement is retained only with probability
. Due to such loss, the phase measurement uncertainty
of an entangled state interferometer will go as
which is clearly undesirable.
Some physical systems, however, naturally suffer very little loss, and
can keep entangled states intact for long times. Photons
unfortunately do not have that feature, but certain atomic states,
such as hyperfine transitions, can be very long lived. Thus, many of
the concepts derived in the context of quantum states of light,
actually turn out to be more useful when applied to quantum states of
matter.