Quantum Fisher Information as a Predictor of Decoherence in the Preparation of Spin-Cat States for Quantum Metrology

TL;DR

This paper explores how quantum Fisher information can predict decoherence in spin-cat states used for quantum metrology, highlighting its role in assessing state robustness against entanglement-induced decoherence.

Contribution

It introduces quantum Fisher information as a key metric for predicting and quantifying decoherence in non-classical states during quantum metrology.

Findings

Quantum Fisher information predicts decoherence effectively.

Spin-cat states are highly susceptible to decoherence.

Field occupation levels influence decoherence rates.

Abstract

In its simplest form, decoherence occurs when a quantum state is entangled with a second state, but the results of measurements made on the second state are not accessible. As the second state has effectively "measured" the first, in this paper we argue that the quantum Fisher information is the relevant metric for predicting and quantifying this kind of decoherence. The quantum Fisher information is usually used to determine an upper bound on how precisely measurements on a state can be used to estimate a classical parameter, and as such it is an important resource. Quantum enhanced metrology aims to create non-classical states with large quantum Fisher information and utilise them in precision measurements. In the process of doing this it is possible for states to undergo decoherence, for instance atom-light interactions used to create coherent superpositions of atomic states may result in atom-light entanglement. Highly non-classical states, such as spin-cat states (Schr\"odinger cat states constructed from superpositions of collective spins) are shown to be highly susceptible to this kind of decoherence. We also investigate the required field occupation of the second state, such that this decoherence is negligible.