Multi-qubit gates and Schrödinger cat states in an optical clock | JILA

Author	Alec Cao William Eckner Theodor Yelin Aaron Young Sven Jandura Lingfeng Yan Kyungtae Kim Guido Pupillo Jun Ye Nelson Oppong Adam Kaufman
Abstract	Many-particle entanglement is a key resource for achieving the fundamental precision limits of a quantum sensor1. Optical atomic clocks2, the current state of the art in frequency precision, are a rapidly emerging area of focus for entanglement-enhanced metrology3–6. Augmenting tweezer-based clocks featuring microscopic control and detection7–10 with the high-fidelity entangling gates developed for atom-array information processing11,12 offers a promising route towards making use of highly entangled quantum states for improved optical clocks.
Year of Publication	2024
Date Published	2024/09/01
Journal Title	Nature
Volume	634
Issue	8033
Start Page or Article ID	315-320
ISBN Number	1476-4687
PDF	Multi-qubit gates_tweezer optical clock Nature 2024.pdf2.13 MB
DOI	10.1038/s41586-024-07913-z
URL	https://doi.org/10.1038/s41586-024-07913-z
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JILA PI	Adam Kaufman Jun Ye
Related JILA Highlights	JILA Fellow and NIST Physicist Adam Kaufman Combines Multiple Atomic Clocks into One System
Associated Institutes	Q-SEnSE JILA-PFC
	Journal Article
JILA Topics	Atomic & Molecular Physics Precision Measurement Quantum Information Science & Technology
Publication Status	Published
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