Related papers: Practical limits for large-momentum-transfer clock atom interferometers

Practical limits for large-momentum-transfer clock atom interferometers

URL: http://arxiv.org/abs/2206.05145v1
Date: Fri, 10 Jun 2022 14:39:03 GMT
Title: Practical limits for large-momentum-transfer clock atom interferometers
Authors: Mauro Chiarotti, Jonathan N. Tinsley, Satvika Bandarupally, Shamaila Manzoor, Michele Sacco, Leonardo Salvi and Nicola Poli
Abstract summary: Atom interferometry on optical clock transitions is being pursued for numerous long-baseline experiments both terrestrially and for future space missions. Here we show that to sequentially apply such a large momentum via $pi$ pulses places stringent requirements on the frequency noise of the interferometry laser. This is due to imperfect pulse fidelity in the presence of noise and is apparent even for an atom at rest interacting with resonant light.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Atom interferometry on optical clock transitions is being pursued for numerous long-baseline experiments both terrestrially and for future space missions. Crucial to meeting these experiments' required sensitivities is the implementation of large momentum transfer ($>$10$^3\hbar k$). Here we show that to sequentially apply such a large momentum via $\pi$ pulses places stringent requirements on the frequency noise of the interferometry laser, finding that the linewidth is required to be considerably lower than has previously been suggested. This is due to imperfect pulse fidelity in the presence of noise and is apparent even for an atom at rest interacting with resonant light, making this a fundamental constraint on operational fidelity for a given laser and pulse sequence. Within this framework, we further present and analyse two high-power, frequency-stabilised laser sources designed to perform interferometry on the $^1$S$_0$ - $^3$P$_0$ clock transitions of cadmium and strontium, respectively operating at 332 nm and 698 nm.

Related papers

Collinear three-photon excitation of a strongly forbidden optical clock transition [0.0]
We show coherent excitation of the clock transition in bosonic $88$Sr using a novel collinear three-photon process in a weak magnetic field. The absence of nuclear spin in bosonic isotopes offers decreased sensitivity to magnetic fields and optical lattice light shifts.
arXiv Detail & Related papers (2024-06-12T06:10:28Z)
Finite Pulse-Time Effects in Long-Baseline Quantum Clock Interferometry [45.73541813564926]
We study the interplay of the quantum center-of-mass $-$ that can become delocalized $-$ together with the internal clock transitions. We show at the example of a Gaussian laser beam that the proposed quantum-clock interferometers are stable against perturbations from varying optical fields.
arXiv Detail & Related papers (2023-09-25T18:00:03Z)
Continuous dynamical decoupling of optical $^{171}$Yb$^{+}$ qudits with radiofrequency fields [45.04975285107723]
We experimentally achieve a gain in the efficiency of realizing quantum algorithms with qudits. Our results are a step towards the realization of qudit-based algorithms using trapped ions.
arXiv Detail & Related papers (2023-05-10T11:52:12Z)
Wavefront Curvature in Optical Atomic Beam Clocks [0.0]
Recent demonstrations of compact optical clocks, employing thermal atomic beams, have achieved short-term fractional frequency instabilities in the $10-16$. A serious challenge inherent in compact clocks is the necessarily smaller optical beams, which results in rapid variation in interrogating wavefronts. Here we develop a model for Ramsey-Bord'e interferometery using optical fields with curved wavefronts.
arXiv Detail & Related papers (2022-12-01T06:57:23Z)
Phase Randomness in a Semiconductor Laser: the Issue of Quantum Random Number Generation [83.48996461770017]
This paper describes theoretical and experimental methods for estimating the degree of phase randomization in a gain-switched laser. We show that the interference signal remains quantum in nature even in the presence of classical phase drift in the interferometer.
arXiv Detail & Related papers (2022-09-20T14:07:39Z)
Enhancing strontium clock atom interferometry using quantum optimal control [0.09786690381850353]
We study QOC pulses for strontium clock interferometry and demonstrate their advantage over basic square pulses. This could improve the scale of large momentum transfer in Sr clock interferometers, paving the way to achieve scientific goals.
arXiv Detail & Related papers (2022-07-26T23:56:33Z)
Ultra-long photonic quantum walks via spin-orbit metasurfaces [52.77024349608834]
We report ultra-long photonic quantum walks across several hundred optical modes, obtained by propagating a light beam through very few closely-stacked liquid-crystal metasurfaces. With this setup we engineer quantum walks up to 320 discrete steps, far beyond state-of-the-art experiments.
arXiv Detail & Related papers (2022-03-28T19:37:08Z)
A continuous, sub-Doppler-cooled atomic beam interferometer for inertial sensing [0.0]
We present the first demonstration of an inertially sensitive atomic interferometer based on a continuous, rather than pulsed, atomic beam at sub-Doppler temperatures. We demonstrate 30% fringe contrast in continuous, inertially sensitive interference fringes at interrogation time. We provide a demonstration of zero-dead-time phase-shear readout of atom interferometer phase, achieving a measurement rate up to 160Hz.
arXiv Detail & Related papers (2021-12-17T18:22:37Z)
Dispersive optical systems for scalable Raman driving of hyperfine qubits [45.82374977939355]
We introduce a new method for generating amplitude modulation by phase modulating a laser. This approach is passively stable, offers high efficiency, and is compatible with high-power laser sources. We benchmark this new approach by globally driving an array of $sim 300$ neutral $87$Rb atomic qubits trapped in optical tweezers.
arXiv Detail & Related papers (2021-10-27T18:00:00Z)
Hyper Ramsey-Bord\'e matter-wave interferometry for robust quantum sensors [0.0]
A new generation of atomic sensors using ultra-narrow optical clock transitions and composite pulses are pushing quantum engineering control to a very high level of precision. We propose a new version of Ramsey-Bord'e interferometry introducing arbitrary composite laser pulses with tailored pulse duration, Rabi field, detuning and phase-steps. We present, for the first time, new developments for robust hyper Ramsey-Bord'e and Mach-Zehnder interferometers.
arXiv Detail & Related papers (2020-12-07T17:47:28Z)
Multidimensional synthetic chiral-tube lattices via nonlinear frequency conversion [57.860179997051915]
We propose and experimentally realize all-optical synthetic dimensions involving specially tailored simultaneous short- and long-range interactions. We implement a synthetic gauge field with nonzero magnetic flux and observe the associated multidimensional dynamics of frequency combs.
arXiv Detail & Related papers (2020-02-20T07:08:35Z)

This list is automatically generated from the titles and abstracts of the papers in this site.