Related papers: Enhanced sensing of weak anharmonicities through coherences in dissipatively coupled anti-PT symmetric systems

Enhanced sensing of weak anharmonicities through coherences in dissipatively coupled anti-PT symmetric systems

URL: http://arxiv.org/abs/2010.12954v1
Date: Sat, 24 Oct 2020 18:59:00 GMT
Title: Enhanced sensing of weak anharmonicities through coherences in dissipatively coupled anti-PT symmetric systems
Authors: Jayakrishnan M. P. Nair, Debsuvra Mukhopadhyay, G. S. Agarwal
Abstract summary: We propose an alternate method relevant to dissipative systems, especially those coupled to the vacuum of the electromagnetic fields. In such systems, which typically show anti-PT symmetry and do not require the incorporation of gain, vacuum induces coherence between two modes. We demonstrate how this coherence can be exploited for the enhanced sensing of very weak anhamonicities at low pumping rates.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In the last few years, the great utility of PT-symmetric systems in sensing small perturbations has been recognized. Here, we propose an alternate method relevant to dissipative systems, especially those coupled to the vacuum of the electromagnetic fields. In such systems, which typically show anti-PT symmetry and do not require the incorporation of gain, vacuum induces coherence between two modes. Owing to this coherence, the linear response acquires a pole on the real axis. We demonstrate how this coherence can be exploited for the enhanced sensing of very weak anhamonicities at low pumping rates. Higher drive powers ($\sim 0.1$ W), on the other hand, generate new domains of coherences. Our results are applicable to a wide class of systems, and we specifically illustrate the remarkable sensing capabilities in the context of a weakly anharmonic Yttrium Iron Garnet (YIG) sphere interacting with a cavity via a tapered fiber waveguide. A small change in the anharmonicity leads to a substantial change in the induced spin current.

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