Critical quantum metrology with fully-connected models: from Heisenberg to Kibble–Zurek scaling

Louis Garbe*, Obinna Abah, Simone Felicetti, Ricardo Puebla*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

25 Citations (Scopus)
47 Downloads (Pure)

Abstract

Phase transitions represent a compelling tool for classical and quantum sensing applications. It has been demonstrated that quantum sensors can in principle saturate the Heisenberg scaling, the ultimate precision bound allowed by quantum mechanics, in the limit of large probe number and long measurement time. Due to the critical slowing down, the protocol duration time is of utmost relevance in critical quantum metrology. However, how the long-time limit is reached remains in general an open question. So far, only two dichotomic approaches have been considered, based on either static or dynamical properties of critical quantum systems. Here, we provide a comprehensive analysis of the scaling of the quantum Fisher information for different families of protocols that create a continuous connection between static and dynamical approaches. In particular, we consider fully-connected models, a broad class of quantum critical systems of high experimental relevance. Our analysis unveils the existence of universal precision-scaling regimes. These regimes remain valid even for finite-time protocols and finite-size systems. We also frame these results in a general theoretical perspective, by deriving a precision bound for arbitrary time-dependent quadratic Hamiltonians.
Original languageEnglish
Article number035010
JournalQuantum Science and Technology
Volume7
Issue number3
Early online date19 May 2022
DOIs
Publication statusPublished - 01 Jul 2022

Keywords

  • Paper
  • quantum metrology
  • quantum phase transitions
  • quantum critical phenomena
  • Kibble–Zurek mechanism
  • fully-connected models

Fingerprint

Dive into the research topics of 'Critical quantum metrology with fully-connected models: from Heisenberg to Kibble–Zurek scaling'. Together they form a unique fingerprint.

Cite this