<p>Understanding and controlling non-equilibrium dynamics in quantum many-body systems is a fundamental challenge in modern physics<sup><CitationRef AdditionalCitationIDS="CR2 CR3 CR4" CitationID="CR1">1</CitationRef>–<CitationRef CitationID="CR5">5</CitationRef></sup>, with profound implications for advancing quantum technologies. Typically, periodically driven systems in the absence of conservation laws thermalize to a featureless ‘infinite-temperature’ state, erasing all memory of their initial conditions<sup><CitationRef AdditionalCitationIDS="CR7" CitationID="CR6">6</CitationRef>–<CitationRef CitationID="CR8">8</CitationRef></sup>. However, this pattern can break down through mechanisms such as integrability<sup><CitationRef CitationID="CR9">9</CitationRef></sup>, many-body localization<sup><CitationRef CitationID="CR2">2</CitationRef>,<CitationRef CitationID="CR3">3</CitationRef>,<CitationRef CitationID="CR10">10</CitationRef>,<CitationRef CitationID="CR11">11</CitationRef></sup>, quantum many-body scars<sup><CitationRef CitationID="CR4">4</CitationRef></sup> and Hilbert space fragmentation<sup><CitationRef CitationID="CR12">12</CitationRef>,<CitationRef CitationID="CR13">13</CitationRef></sup>. Here we report the experimental observation of dynamical freezing, a distinct mechanism of thermalization breakdown in driven systems<sup><CitationRef AdditionalCitationIDS="CR15 CR16 CR17 CR18" CitationID="CR14">14</CitationRef>–<CitationRef CitationID="CR19">19</CitationRef></sup>, and demonstrate its application in quantum sensing using an ensemble of approximately 10<sup>4</sup> interacting nitrogen-vacancy (NV) spins in diamond. By precisely controlling the driving frequency and detuning, we observe emergent long-lived spin magnetization and coherent oscillatory micromotions, persisting over timescales exceeding the interaction-limited coherence time (<i>T</i><sub>2</sub>) by more than an order of magnitude. By using these unconventional dynamics, we develop a dynamical-freezing-enhanced a.c. magnetometry that extends optimal sensing times far beyond <i>T</i><sub>2</sub>, outperforming conventional dynamical decoupling magnetometry with a 2.7-fold sensitivity enhancement. Our results not only provide clear experimental observation of dynamical freezing—a peculiar mechanism defying thermalization through emergent conservation laws—but also establish a robust control method generally applicable to diverse physical platforms, with broad implications in quantum metrology and beyond.</p>

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Dynamical freezing for magnetometry in an interacting spin ensemble

  • Ya-Nan Lu,
  • Dong Yuan,
  • Yixuan Ma,
  • Yan-Qing Liu,
  • Si Jiang,
  • Xiang-Qian Meng,
  • Yi-Jie Xu,
  • Xiu-Ying Chang,
  • Chong Zu,
  • Hong-Zheng Zhao,
  • Dong-Ling Deng,
  • Lu-Ming Duan,
  • Pan-Yu Hou

摘要

Understanding and controlling non-equilibrium dynamics in quantum many-body systems is a fundamental challenge in modern physics15, with profound implications for advancing quantum technologies. Typically, periodically driven systems in the absence of conservation laws thermalize to a featureless ‘infinite-temperature’ state, erasing all memory of their initial conditions68. However, this pattern can break down through mechanisms such as integrability9, many-body localization2,3,10,11, quantum many-body scars4 and Hilbert space fragmentation12,13. Here we report the experimental observation of dynamical freezing, a distinct mechanism of thermalization breakdown in driven systems1419, and demonstrate its application in quantum sensing using an ensemble of approximately 104 interacting nitrogen-vacancy (NV) spins in diamond. By precisely controlling the driving frequency and detuning, we observe emergent long-lived spin magnetization and coherent oscillatory micromotions, persisting over timescales exceeding the interaction-limited coherence time (T2) by more than an order of magnitude. By using these unconventional dynamics, we develop a dynamical-freezing-enhanced a.c. magnetometry that extends optimal sensing times far beyond T2, outperforming conventional dynamical decoupling magnetometry with a 2.7-fold sensitivity enhancement. Our results not only provide clear experimental observation of dynamical freezing—a peculiar mechanism defying thermalization through emergent conservation laws—but also establish a robust control method generally applicable to diverse physical platforms, with broad implications in quantum metrology and beyond.