Strong coupling on a forbidden transition in strontium and nondestructive atom counting

Norcia, Matthew A.; Thompson, James K.

doi:10.1103/physreva.93.023804

Cited by 32 publications

(35 citation statements)

References 49 publications

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“…Ultimately, the relatively modest single-atom cooperativity C = 4 g 2 /κΓ = 0.045 for the apparatus in this work will be a limiting factor for high detection efficiency at low atom number, as compared with previous demonstrations of high-fidelity cavity detection of Yb [32] and Sr [33]. However, quantum non-destructive detection is still feasible in our cavity above the critical atom number N crit = 28, with significant metrological gain possible in the N ≈ 10 4 range.…”

Section: Resultsmentioning

confidence: 91%

Cavity-enhanced non-destructive detection of atoms for an optical lattice clock

Hobson¹,

Bowden²,

Vianello³

et al. 2019

Opt. Express

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We demonstrate a new method of cavity-enhanced non-destructive detection of atoms for a strontium optical lattice clock. The detection scheme is shown to be linear in atom number up to at least 2 × 10 4 atoms, to reject technical noise sources, to achieve signal to noise ratio close to the photon shot noise limit, to provide spatially uniform atom-cavity coupling, and to minimize inhomogeneous ac Stark shifts. These features enable detection of atoms with minimal perturbation to the atomic state, a critical step towards realizing an ultra-high-stability, quantum-enhanced optical lattice clock.

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Section: Resultsmentioning

confidence: 91%

Cavity-enhanced non-destructive detection of atoms for an optical lattice clock

Hobson¹,

Bowden²,

Vianello³

et al. 2019

Opt. Express

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“…1a and Refs. [16,17,28]). We tune a TEM00 resonance of the cavity at frequency ω c to be near resonance with the dipole-forbidden singlet to triplet optical transition 1 S 0 to 3 P 1 at frequency ω 0 or wavelength 689 nm (see Fig.…”

mentioning

confidence: 99%

Magnetically Induced Optical Transparency on a Forbidden Transition in Strontium for Cavity-Enhanced Spectroscopy

et al. 2017

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In this work we realize a narrow spectroscopic feature using a technique that we refer to as magnetically-induced optical transparency. A cold ensemble of 88 Sr atoms interacts with a single mode of a high-finesse optical cavity via the 7.5 kHz linewidth, spin forbidden 1 S0 to 3 P1 transition. By applying a magnetic field that shifts two excited state Zeeman levels, we open a transmission window through the cavity where the collective vacuum Rabi splitting due to a single level would create destructive interference for probe transmission. The spectroscopic feature approaches the atomic transition linewidth, which is much narrower than the cavity linewidth, and is highly immune to the reference cavity length fluctuations that limit current state-of-the-art laser frequency stability.There has been a dedicated effort in recent years to improve the frequency stability of lasers [1] used to probe optical atomic clocks [2][3][4]. Improvements in these precision measurement technologies are essential for advancing a broad range of scientific pursuits such as searching for variations in fundamental constants [5] , gravitational wave detection [6,7], and physics beyond the standard model [8,9]. Associated improvements in atomic clocks would also advance recent work on relativistic geodesy [10].The frequency stability of current state-of-the-art lasers is limited by thermal fluctuations in the reference cavity mirror coatings, substrates, and spacer [11]. This problem can be alleviated by creating systems that rely on an ensemble of atoms, rather than the reference cavity, to achieve stable optical coherence. Recent approaches include cavity-assisted non-linear spectroscopy [12][13][14] and superradiant lasers [15][16][17][18]. Both approaches use narrow forbidden transitions with linewidths ranging from 7.5 kHz to 1 mHz. These novel systems are absolute frequency references and are intrinsically less sensitive to both fundamental thermal and technical vibrations that create noise on the optical cavity's resonance frequency.Here we demonstrate a new linear spectroscopy approach in which a static magnetic field can induce optical transparency in the transmission spectrum of an optical cavity. The center frequency of the transparency window is shown to be insensitive to changes in the cavityresonance frequency and to first-order Zeeman shifts. The observed linewidth of the feature approaches the natural linewidth of the 7.5 kHz optical transition and can be insensitive to inhomogeneous broadening of the atomic transition frequency. The linewidth of the feature is an important attribute for laser stabilization, as a laser stabilized to a narrow spectroscopic feature is less sensitive to technical offsets than a laser stabilized to a broader feature. In the future, it might be possible to extend this technique to even narrower optical transitions for enhanced spectroscopic sensitivity in atoms such as calcium and magnesium.In partial analogy to electromagnetically induced transparency (EIT) [19][20][21], we refer to this eff...

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“…7a). In ref [17], such a probing technique enabled the demonstration of cavity enhanced atom counting with levels of precision and scattering compatible with the generation of spin squeezed states. In this work, a mode of a high-finesse optical cavity (linewidth κ 160 kHz) was placed on resonance with the 7.5 kHz linewidth 1 S 0 to 3 P 1 transition in 88 Sr. For an atom number of N = 1.25 × 10 5 , the observed vacuum Rabi splitting was roughly 5 MHz, placing the system deep in the desirable strong collective coupling, bad cavity regime Ω κ γ.…”

Section: Spin Squeezing and Nondestructive Atom Countingmentioning

confidence: 99%

“…In order to generate spin squeezed states using the nondestructive measurements presented in ref. [17], the measurements must be applied in conjunction with high-fidelity rotations on the optical clock transition. Thus, both of these methods require the ability to perform precise optical rotations on the clock transition, which requires tight spatial confinement of the atoms along the direction from which the clock laser is applied in order to eliminate the effects of Doppler shifts and photon recoil.…”

Section: Spin Squeezing and Nondestructive Atom Countingmentioning

confidence: 99%

Coupling atoms to cavities using narrow linewidth optical transitions: applications to frequency metrology

Norcia¹

2019

J. Phys. B: At. Mol. Opt. Phys.

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Narrow linewidth optical atomic transitions provide a valuable resource for frequency metrology, and form the basis of today's most precise and accurate clocks. Recent experiments have demonstrated that ensembles of atoms can be interfaced with the mode of an optical cavity using such transitions, and that atom-cavity interactions can dominate over decoherence processes even when the atomic transition that mediates the interactions is very weak. This scenario enables new opportunities for optical frequency metrology, including techniques for nondestructive readout and entanglement enhancement for optical lattice clocks, methods for cavity-enhanced laser frequency stabilization, and high-precision active optical frequency references based on superradiant emission. This tutorial provides a pedagogical description of the physics governing atom-cavity coupling with narrow linewidth optical transitions, and describes several examples of applications to optical frequency metrology.

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Strong coupling on a forbidden transition in strontium and nondestructive atom counting

Cited by 32 publications

References 49 publications

Cavity-enhanced non-destructive detection of atoms for an optical lattice clock

Cavity-enhanced non-destructive detection of atoms for an optical lattice clock

Magnetically Induced Optical Transparency on a Forbidden Transition in Strontium for Cavity-Enhanced Spectroscopy

Coupling atoms to cavities using narrow linewidth optical transitions: applications to frequency metrology

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