Time-optimal force sensing with ultracold atoms

Nicolas Ombredane; Eloi Flament; Charles Babin; Dominique Sugny; David Gu\'ery-Odelin; B. Peaudecerf

arXiv:2512.17836·cond-mat.quant-gas·December 22, 2025

Time-optimal force sensing with ultracold atoms

Nicolas Ombredane, Eloi Flament, Charles Babin, Dominique Sugny, David Gu\'ery-Odelin, B. Peaudecerf

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TL;DR

This paper presents a time-optimal quantum sensing method using ultracold atoms in a shaken optical lattice, achieving high sensitivity through optimal control protocols derived from Fisher information, with experimental validation.

Contribution

It introduces a novel Fisher information-based framework for designing time-optimal control protocols in ultracold atom sensors, demonstrating enhanced sensitivity and robustness.

Findings

01

Protocols achieve high sensitivity in force detection.

02

Optimal dynamics form interferometer-like structures.

03

Experimental results confirm robustness and precision.

Abstract

We develop a time-optimal approach to force sensing using a Bose-Einstein condensate in a shaken optical lattice. Optimal control protocols are derived from a Fisher information framework and yield optimal dynamics that spontaneously organize in intereferometer-like structures, where multiple interferences combine to maximize sensitivity. We analyse how measurement precision scales with control time and how the finite momentum dispersion of the condensate changes the optimal dynamics, observing an abrupt change of conformation from single- to double-folded interference structures for robust controls. The protocols are implemented experimentally for cold atoms subjected to inertial and magnetic forces, demonstrating high sensitivity and robustness. Our approach establishes a general route to time-optimal quantum sensing beyond standard interferometric architectures, applcable across all…

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Taxonomy

TopicsCold Atom Physics and Bose-Einstein Condensates · Mechanical and Optical Resonators · Quantum chaos and dynamical systems