Collective quantum enhancement in critical quantum sensing
- URL: http://arxiv.org/abs/2407.18055v1
- Date: Thu, 25 Jul 2024 14:08:39 GMT
- Title: Collective quantum enhancement in critical quantum sensing
- Authors: Uesli Alushi, Alessandro Coppo, Valentina Brosco, Roberto Di Candia, Simone Felicetti,
- Abstract summary: We show that collective quantum advantage can be achieved with a multipartite critical quantum sensor based on a parametrically coupled Kerr resonators chain.
We derive analytical solutions for the low-energy spectrum of this unconventional quantum many-body system.
We evaluate the scaling of the quantum Fisher information with respect to fundamental resources, and find that the critical chain achieves a quadratic enhancement in the number of resonators.
- Score: 37.69303106863453
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Critical systems represent a valuable resource in quantum sensing and metrology. Critical quantum sensing (CQS) protocols can be realized using finite-component phase transitions, where criticality is not due to the thermodynamic limit but rather to the rescaling of the system parameters. In particular, the second-order phase transitions of parametric Kerr resonators are of high experimental relevance, as they can be implemented and controlled with various quantum technologies currently available. Here, we show that collective quantum advantage can be achieved with a multipartite critical quantum sensor based on a parametrically coupled Kerr resonators chain in the weak-nonlinearity limit. We derive analytical solutions for the low-energy spectrum of this unconventional quantum many-body system, which is composed of \emph{locally} critical elements. We then assess the performance of an adiabatic CQS protocol, comparing the coupled-resonator chain with an equivalent ensemble of independent critical sensors. We evaluate the scaling of the quantum Fisher information with respect to fundamental resources, and find that the critical chain achieves a quadratic enhancement in the number of resonators. Beyond the advantage found in the case of zero Kerr, we find that there is a collective enhancement even in the scenario of finite Kerr nonlinearity.
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