Dressed-State Spectroscopy and Magic Trapping of Microwave-Shielded NaCs Molecules

Siwei Zhang; Weijun Yuan; Niccolò Bigagli; Claire Warner; Ian Stevenson; Sebastian Will

doi:10.1103/PhysRevLett.133.263401

Dressed-State Spectroscopy and Magic Trapping of Microwave-Shielded NaCs Molecules

Siwei Zhang, Weijun Yuan, Niccolò Bigagli, Claire Warner, Ian Stevenson, Sebastian Will

Columbia University

Research output: Contribution to journal › Article › peer-review

Abstract

We report on the optical polarizability of microwave-shielded ultracold NaCs molecules in an optical dipole trap. While dressing a pair of rotational states with a microwave field, we observe a marked dependence of the optical polarizability on the intensity and detuning of the dressing field. To precisely characterize differential energy shifts between dressed rotational states, we establish dressed-state spectroscopy. For strong dressing fields, we find that a magic rotational transition can be engineered and demonstrate its insensitivity to laser intensity fluctuations. The results of this Letter have direct relevance for evaporative cooling and the recent demonstration of molecular Bose-Einstein condensates [Bigagli et al., Nature (London) 631, 289 (2024)NATUAS0028-083610.1038/s41586-024-07492-z] and may open a door to precision microwave spectroscopy in interacting many-body systems of microwave-shielded molecules.

Original language	English
Article number	263401
Journal	Physical Review Letters
Volume	133
Issue number	26
DOIs	https://doi.org/10.1103/PhysRevLett.133.263401
Publication status	Published - 31 Dec 2024
Externally published	Yes

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title = "Dressed-State Spectroscopy and Magic Trapping of Microwave-Shielded NaCs Molecules",

abstract = "We report on the optical polarizability of microwave-shielded ultracold NaCs molecules in an optical dipole trap. While dressing a pair of rotational states with a microwave field, we observe a marked dependence of the optical polarizability on the intensity and detuning of the dressing field. To precisely characterize differential energy shifts between dressed rotational states, we establish dressed-state spectroscopy. For strong dressing fields, we find that a magic rotational transition can be engineered and demonstrate its insensitivity to laser intensity fluctuations. The results of this Letter have direct relevance for evaporative cooling and the recent demonstration of molecular Bose-Einstein condensates [Bigagli et al., Nature (London) 631, 289 (2024)NATUAS0028-083610.1038/s41586-024-07492-z] and may open a door to precision microwave spectroscopy in interacting many-body systems of microwave-shielded molecules.",

author = "Siwei Zhang and Weijun Yuan and Niccol{\`o} Bigagli and Claire Warner and Ian Stevenson and Sebastian Will",

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T1 - Dressed-State Spectroscopy and Magic Trapping of Microwave-Shielded NaCs Molecules

AU - Zhang, Siwei

AU - Yuan, Weijun

AU - Bigagli, Niccolò

AU - Warner, Claire

AU - Stevenson, Ian

AU - Will, Sebastian

PY - 2024/12/31

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AB - We report on the optical polarizability of microwave-shielded ultracold NaCs molecules in an optical dipole trap. While dressing a pair of rotational states with a microwave field, we observe a marked dependence of the optical polarizability on the intensity and detuning of the dressing field. To precisely characterize differential energy shifts between dressed rotational states, we establish dressed-state spectroscopy. For strong dressing fields, we find that a magic rotational transition can be engineered and demonstrate its insensitivity to laser intensity fluctuations. The results of this Letter have direct relevance for evaporative cooling and the recent demonstration of molecular Bose-Einstein condensates [Bigagli et al., Nature (London) 631, 289 (2024)NATUAS0028-083610.1038/s41586-024-07492-z] and may open a door to precision microwave spectroscopy in interacting many-body systems of microwave-shielded molecules.

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Dressed-State Spectroscopy and Magic Trapping of Microwave-Shielded NaCs Molecules

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