Ramsey interferometry explained

Ramsey interferometry, also known as the separated oscillating fields method,^[1] is a form of particle interferometry that uses the phenomenon of magnetic resonance to measure transition frequencies of particles. It was developed in 1949 by Norman Ramsey,^[2] who built upon the ideas of his mentor, Isidor Isaac Rabi, who initially developed a technique for measuring particle transition frequencies. Ramsey's method is used today in atomic clocks and in the SI definition of the second. Most precision atomic measurements, such as modern atom interferometers and quantum logic gates, have a Ramsey-type configuration.^[3] A more modern method, known as Ramsey–Bordé interferometry uses a Ramsey configuration and was developed by French physicist Christian Bordé and is known as the Ramsey–Bordé interferometer. Bordé's main idea was to use atomic recoil to create a beam splitter of different geometries for an atom-wave. The Ramsey–Bordé interferometer specifically uses two pairs of counter-propagating interaction waves, and another method named the "photon-echo" uses two co-propagating pairs of interaction waves.^[4] ^[5] __TOC__

Introduction

A main goal of precision spectroscopy of a two-level atom is to measure the absorption frequency

\omega₀

between the ground state and excited state of the atom. One way to accomplish this measurement is to apply an external oscillating electromagnetic field at frequency

\omega

and then find the difference

\Delta

(also known as the detuning) between

\omega

and

\omega₀

(\Delta=\omega-\omega₀₎

by measuring the probability to transfer to . This probability can be maximized when, when the driving field is in resonance with the transition frequency of the atom. Looking at this probability of transition as a function of the detuning, the narrower the peak around

\Delta=0

, the more precision there is. If the peak were very broad about, then it would be difficult to distinguish precisely where is located due to many values of having close to the same probability.

Physical principles

The Rabi method

A simplified version of the Rabi method consists of a beam of atoms, all having the same speed

and the same direction, sent through one interaction zone of length

. The atoms are two-level atoms with a transition energy of

\hbar\omega₀

(this is defined by applying a field

B_\|

in an excitation direction

\hat{z}

, and thus

\omega₀=\gamma|B_\||

, the Larmor frequency), and with an interaction time of

\tau=L/v

in the interaction zone. In the interaction zone, a monochromatic oscillating magnetic field

B_\perp\cos(\omegat)

is applied perpendicular to the excitation direction, and this will lead to Rabi oscillations between and at a frequency of

\Omega_\perp=\gamma|B_\perp|

.^[6]

The Hamiltonian in the rotating frame (including the rotating-wave approximation) is

\hat{H}=-

	\hbar\Delta
	2

\hat{\sigma_z}+

	\hbar\Omega_\perp
	2

\hat{\sigma_x}.

The probability of transition from and can be found from this Hamiltonian and is

P(\Delta,v,L,\Omega_\perp)=

\left(	\Delta
	\Omega_\perp

\right)²

2\left(	L
	2v

\sin

	2
\sqrt{\Omega
	\perp

+\Delta^2}\right).

This probability will be at its maximum when

\Omega_\perp\tau=\pi

. The line width

\delta

of this

P(\Delta,\Omega_\perp)

vs.

\Delta/\Omega_\perp

determines the precision of the measurement. Because

\delta\sim\Omega_\perp\sim\pi/\tau\sim\piv/L

, by increasing

\tau

, and correspondingly decreasing

\Omega_\perp

so that their product is

\pi

, the precision of the measurement increases; i.e. the peak of the graph becomes narrower.

In reality, however, inhomogeneities such as the atoms having a distribution of velocities or there being an inhomogeneous

B_\perp

will cause the line shape to broaden and lead to decreased precision. Having a distribution of velocities means having a distribution of interaction times, and therefore there would be many angles through which state vectors would flip on the Bloch sphere. There would be an optimal length in the Rabi setup that would give the greatest precision, but it would not be possible to increase the length

infinitely and expect ever increasing precision, as was the case in the perfect, simple Rabi model.

The Ramsey method

Ramsey improved upon Rabi's method by splitting the one interaction zone into two very short interaction zones, each applying a

\pi/2

pulse. The two interaction zones are separated by a much longer non-interaction zone. By making the two interaction zones very short, the atoms spend a much shorter time in the presence of the external electromagnetic fields than they would in the Rabi model. This is advantageous because the longer the atoms are in the interaction zone, the more inhomogeneities (such as an inhomogeneous field) lead to reduced precision in determining

\Delta

. The non-interaction zone in Ramsey's model can be made much longer than the one interaction zone in Rabi's method because there is no perpendicular field

B_\perp

being applied in the non-interaction zone (although there is still

The primary improvement from the Ramsey method is because the main peak resonance frequency represents an average over the frequencies (and inhomogeneities) in the non-interaction region between the cavities, whereas with the Rabi method the inhomogeneities in the interaction region lead to line broadening. An additional advantage of the Ramsey method for microwave or optical transitions is that the non-interaction region can be made much longer than an interaction region with the Rabi method, resulting in narrower lines.

The Hamiltonian in the rotating frame for the two interaction zones is the same for that of the Rabi method, and in the non-interaction zone the Hamiltonian is only the

\hat{\sigma_z}

term. First a

\pi/2

pulse is applied to atoms in the ground state, whereupon the atoms reach the non-interaction zone, and the spins precess about the z axis for time

. Another

\pi/2

pulse is applied, and the probability measured—practically this experiment must be done many times, because one measurement will not be enough to determine the probability of measuring any value (see the Bloch sphere description below). By applying this evolution to atoms of one velocity, the probability to find the atom in the excited state as a function of the detuning and time of flight

in the non-interaction zone is (taking

|\Delta|\ll\Omega_\perp

here)

P(T,\Delta)=

2\left(	\DeltaT
	2

\cos

\right)=

2\left(	\DeltaL
	2v

\cos

\right).

This probability function describes the well-known Ramsey fringes.

If there is a distribution of velocities and a "hard pulse"

\left(|\Delta|\ll\Omega_\perp\right)

is applied in the interaction zones so that all of the spins of the atoms are rotated

\pi/2

on the Bloch sphere regardless of whether or not they all were excited to exactly the same resonance frequency, the Ramsey fringes will look very similar to those discussed above. If a hard pulse is not applied, then the variation in interaction times must be taken into account. What results are Ramsey fringes in an envelope in the shape of the Rabi method probability for atoms of one velocity. The line width

\delta

of the fringes in this case is what determines the precision with which

\Delta

can be determined and is

\delta\sim

	1
	T

\sim

	v
	L

By increasing the time of flight

in the non-interaction zone, or equivalently increasing the length

of the non-interaction zone, the line width can be substantially improved, by a factor of 10 or more, over that of other methods.

Because Ramsey's model allows a longer observation time, one can more precisely determine

\omega₀

. This is a statement of the time-energy uncertainty principle: the larger the uncertainty in the time domain, the smaller the uncertainty in the energy domain, or equivalently the frequency domain. Thought of another way, if two waves of almost exactly the same frequency are superimposed upon each other, then it will be impossible to distinguish them if the resolution of our eyes is larger than the difference between the two waves. Only after a long period of time will the difference between two waves become large enough to differentiate the two.

Early Ramsey interferometers used two interaction zones separated in space, but it is also possible to use two pulses separated in time, as long as the pulses are coherent. In the case of time-separated pulses, the longer the time between pulses, the more precise the measurement.

Applications of the Ramsey interferometer

Atomic clocks and the SI definition of the second

An atomic clock is fundamentally an oscillator whose frequency

\omega

is matched to that of an atomic transition of a two-level atom,

\omega₀

. The oscillator is the parallel external electromagnetic field in the non-interaction zone of the Ramsey–Bordé interferometer. By measuring the transition rate from the excited to the ground state, one can tune the oscillator so that

\omega=\omega₀

by finding the frequency that yields the maximum transition rate. Once the oscillator is tuned, the number of oscillations of the oscillator can be counted electronically to give a certain time interval (e.g. the SI second, which is 9,192,631,770 periods of a cesium-133

Experiments of Serge Haroche

Serge Haroche won the 2012 Nobel Prize in physics (with David J. Wineland^[7]) for work involving cavity quantum electrodynamics (QED) in which the research group used microwave-frequency photons to verify the quantum description of electromagnetic fields.^[8] Essential to their experiments was the Ramsey interferometer, which they used to demonstrate the transfer of quantum coherence from one atom to another through interaction with a quantum mode in a cavity. The setup is similar to a regular Ramsey interferometer, with key differences being there is a quantum cavity in the non-interaction zone and the second interaction zone has its field phase shifted by some constant relative to the first interaction zone.

If one atom is sent into the setup in its ground state