Atom Interferometry in an Optical Cavity

Hamilton, Paul; Jaffe, Matt; Brown, Justin M.; Maisenbacher, Lothar; Estey, Brian; Müller, Holger

doi:10.1103/physrevlett.114.100405

Cited by 106 publications

(94 citation statements)

References 40 publications

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Section: In Brief We Trapmentioning

confidence: 99%

“…The 11(1) dB of squeezing observed in this work would in principle fully translate to this type of interferometer. In addition to the possibility of using entangled states, performing the final readout via a cavity measurement may allow for reduced technical noise, higher bandwidth, cleaner optical modes, and power buildup for Raman transitions [25].Similarly, higher order transverse modes, atom-chip technologies [26,27], or tailored potentials [28,29] might be combined with the cavity measurement technique presented here to create new varieties of matter-wave Sagnac interferometers and other inertial sensors. The real-time observation of mechanical motion also opens the path to stochastic cooling schemes based on measurement and feedback [30] with applications to more complex systems such as molecules, which can be challenging to laser cool using conventional Doppler cooling methods.…”

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confidence: 99%

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Spatially homogeneous entanglement for matter-wave interferometry created with time-averaged measurements

Cox

Greve

et al. 2016

Phys. Rev. A

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We demonstrate a method to generate spatially homogeneous entangled, spin-squeezed states of atoms appropriate for maintaining a large amount of squeezing even after release into the arm of a matter-wave interferometer or other free space quantum sensor. Using an effective intracavity dipole trap, we allow atoms to move along the cavity axis and time average their coupling to the standing wave used to generate entanglement via collective measurements, demonstrating 11(1) dB of directly observed spin squeezing. Our results show that time averaging in collective measurements can greatly reduce the impact of spatially inhomogeneous coupling to the measurement apparatus.Spin-1/2 atoms must project into either "up" or "down" when measured. For N unentangled atoms, the independent randomness in this quantum projection fundamentally limits the single-shot phase resolution of any quantum sensor to ∆φ SQL = 1/ √ N rad, the standard quantum limit (SQL) [1]. Collective measurements of atoms in optical cavities have recently produced some of the most strongly entangled, spin-squeezed states to date, directly improving the phase resolution of a quantum sensor's "clock hand" by a factor up to 60-70 (roughly 18 dB) in noise variance below the SQL [2,3].Spin-squeezed states could be used to improve a wide range of quantum sensors, with today's best atomic clocks [4][5][6] being particularly promising candidates [7,8]. In this work we focus on preparing spin-squeezed states appropriate for matter-wave atom interferometry with applications including inertial sensing [9], measurements of gravity and freefall, [10,11] and even the search for certain proposed types of dark matter and dark energy [12,13].A major challenge arises for cavity-based atom interferometry and other applications involving release of spinsqueezed atoms into free space. The problem is that the probe mode used to perform the collective measurement is a standing wave, but the atoms are trapped in a 1-dimensional lattice defined by a standing wave cavity mode with a significantly different wavelength. Some atoms will sit in lattice sites positioned near nodes and some near anti-nodes of the entanglement-generating probe light. As a result, the atoms will contribute to the collective measurement with different strengths. In this common case, the large degree of squeezing exists only for this specific coupling configuration and would be largely lost after releasing the atoms into the arm of an interferometer, since their final coupling to the cavity mode or other readout detector will be different from the original configuration [14]. In contrast, we wish to create spatially homogeneous entanglement, quantified by the amount of observed phase resolution beyond the SQL that one can achieve when every atom couples equally to the final measurement apparatus.In this Letter, we demonstrate a method to create ho- FIG. 1. (a)Optical lattice sidebands separated by one free spectral range (FSR) are injected into the cavity to create an axially homogeneous "dipole" trap. Dip...

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Section: In Brief We Trapmentioning

confidence: 99%

mentioning

confidence: 99%

Spatially homogeneous entanglement for matter-wave interferometry created with time-averaged measurements

Cox

Greve

et al. 2016

Phys. Rev. A

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“…For example, a closed-loop system can correct deviations from optimal fitness due to the parasitic lattice reflections discussed in the previous section as long as the deleterious effects are constant from shot-to-shot. Uncertainties in lattice parameters such as the lattice depth or wavelength due to imperfect lattice alignment or the Gouy phase [34,35] may also be corrected for in a closed-loop system.…”

Section: −N Imentioning

confidence: 99%

Atom interferometry using a shaken optical lattice

Weidner

Kosloff

et al. 2017

Phys. Rev. A

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We introduce shaken lattice interferometry with atoms trapped in a one-dimensional optical lattice. By phase modulating (shaking) the lattice, we control the momentum state of the atoms. Through a sequence of shaking functions, the atoms undergo an interferometer sequence of splitting, propagation, reflection, reverse-propagation and recombination. Each shaking function in the sequence is optimized with a genetic algorithm to achieve the desired momentum state transitions. As with conventional atom interferometers, the sensitivity of the shaken lattice interferometer increases with interrogation time. The shaken lattice interferometer may also be optimized to sense signals of interest while rejecting others, such as the measurement of an AC inertial signal in the presence of an unwanted DC signal.

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“…Alternatively, atom interferometry [778,779] is a well-developed field that is routinely used to perform high precision measurements of the gravitational field of the Earth (e.g. [780][781][782][783][784][785][786]). Interferometry of antihydrogen using a Ramsey-Bordé approach [787] has been proposed [788].…”

Section: Antimatter Gravity Experimentsmentioning

confidence: 99%

Experimental progress in positronium laser physics

2018

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Abstract. The field of experimental positronium physics has advanced significantly in the last few decades, with new areas of research driven by the development of techniques for trapping and manipulating positrons using Surko-type buffer gas traps. Large numbers of positrons (typically ≥10 6 ) accumulated in such a device may be ejected all at once, so as to generate an intense pulse. Standard bunching techniques can produce pulses with ns (mm) temporal (spatial) beam profiles. These pulses can be converted into a dilute Ps gas in vacuum with densities on the order of 10 7 cm −3 which can be probed by standard ns pulsed laser systems. This allows for the efficient production of excited Ps states, including long-lived Rydberg states, which in turn facilitates numerous experimental programs, such as precision optical and microwave spectroscopy of Ps, the application of Stark deceleration methods to guide, decelerate and focus Rydberg Ps beams, and studies of the interactions of such beams with other atomic and molecular species. These methods are also applicable to antihydrogen production and spectroscopic studies of energy levels and resonances in positronium ions and molecules. A summary of recent progress in this area will be given, with the objective of providing an overview of the field as it currently exists, and a brief discussion of some future directions.

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Atom Interferometry in an Optical Cavity

Cited by 106 publications

References 40 publications

Spatially homogeneous entanglement for matter-wave interferometry created with time-averaged measurements

Spatially homogeneous entanglement for matter-wave interferometry created with time-averaged measurements

Atom interferometry using a shaken optical lattice

Experimental progress in positronium laser physics

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