I. Majewska scite author profile

Atomic lattice clocks have spurred numerous ideas for tests of fundamental physics, detection of general relativistic effects, and studies of interacting many-body systems. On the other hand, molecular structure and dynamics offer rich energy scales that are at the heart of new protocols in precision measurement and quantum information science. Here we demonstrate a fundamentally distinct type of lattice clock that is based on vibrations in diatomic molecules, and present coherent Rabi oscillations between weakly and deeply bound molecules that persist for 10's of milliseconds. This control is made possible by a state-insensitive magic lattice trap that weakly couples to molecular vibronic resonances and enhances the coherence time between molecules and light by several orders of magnitude. The achieved quality factor Q = 8 × 10 11 results from 30-Hz narrow resonances for a 25-THz clock transition in Sr2. Our technique of extended coherent manipulation is applicable to long-term storage of quantum information in qubits based on ultracold polar molecules, while the vibrational clock enables precise probes of interatomic forces, tests of Newtonian gravitation at ultrashort range, and model-independent searches for electron-to-proton mass ratio variations.

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Photodissociation of ultracold diatomic strontium molecules with quantum state control

McDonald

McGuyer

Apfelbeck

et al. 2016

Nature

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Chemical reactions at ultracold temperatures are expected to be dominated by quantum mechanical effects. Although progress towards ultracold chemistry has been made through atomic photoassociation, Feshbach resonances and bimolecular collisions, these approaches have been limited by imperfect quantum state selectivity. In particular, attaining complete control of the ground or excited continuum quantum states has remained a challenge. Here we achieve this control using photodissociation, an approach that encodes a wealth of information in the angular distribution of outgoing fragments. By photodissociating ultracold (88)Sr2 molecules with full control of the low-energy continuum, we access the quantum regime of ultracold chemistry, observing resonant and nonresonant barrier tunnelling, matter-wave interference of reaction products and forbidden reaction pathways. Our results illustrate the failure of the traditional quasiclassical model of photodissociation and instead are accurately described by a quantum mechanical model. The experimental ability to produce well-defined quantum continuum states at low energies will enable high-precision studies of long-range molecular potentials for which accurate quantum chemistry models are unavailable, and may serve as a source of entangled states and coherent matter waves for a wide range of experiments in quantum optics.

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Ultracold⁸⁸Sr₂molecules in the absolute ground state

et al. 2021

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Transition Strength Measurements to Guide Magic Wavelength Selection in Optically Trapped Molecules

et al. 2020

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Control of Ultracold Photodissociation with Magnetic Fields

McDonald¹,

Majewska²,

Lee³

et al. 2018

Phys. Rev. Lett.

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Photodissociation of a molecule produces a spatial distribution of photofragments determined by the molecular structure and the characteristics of the dissociating light. Performing this basic reaction at ultracold temperatures allows its quantum mechanical features to dominate. In this regime, weak applied fields can be used to control the reaction. Here, we photodissociate ultracold diatomic strontium in magnetic fields below 10 G and observe striking changes in photofragment angular distributions. The observations are in excellent agreement with a multichannel quantum chemistry model that includes nonadiabatic effects and predicts strong mixing of partial waves in the photofragment energy continuum. The experiment is enabled by precise quantum-state control of the molecules.

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I. Majewska

Molecular lattice clock with long vibrational coherence

Photodissociation of ultracold diatomic strontium molecules with quantum state control

Ultracold⁸⁸Sr₂molecules in the absolute ground state

Transition Strength Measurements to Guide Magic Wavelength Selection in Optically Trapped Molecules

Control of Ultracold Photodissociation with Magnetic Fields

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Resources

About

I. Majewska

Molecular lattice clock with long vibrational coherence

Photodissociation of ultracold diatomic strontium molecules with quantum state control

Ultracold88Sr2molecules in the absolute ground state

Transition Strength Measurements to Guide Magic Wavelength Selection in Optically Trapped Molecules

Control of Ultracold Photodissociation with Magnetic Fields

Contact Info

Product

Resources

About

Ultracold⁸⁸Sr₂molecules in the absolute ground state