Extracting information from a superradiant burst using simple measurements

TL;DR

This paper demonstrates that simple homodyne measurements can effectively extract information from superradiant photon bursts, revealing the initial spin state with quantum Fisher information scaling.

Contribution

It shows that a straightforward measurement approach can recover the quantum Fisher information scaling of the initial spin state from superradiant emissions.

Findings

Homodyne measurement recovers N-scaling of quantum Fisher information.

Optimal temporal mode contains vanishing fraction of emitted photons.

Method enables cavity-based readout of solid-state spin ensembles.

Abstract

It is well known that superradiant decay of an ensemble of $N$ spins generates a complex non-classical state of light. Here, we consider the information content of a superradiant burst of photons: how is information encoded in the initial spin state distributed among the emitted photons, and can it be extracted using simple measurements? Despite the complexity of the photonic burst state, we show that a simple homodyne measurement combined with an optimized filter and linear estimator recovers the $N$-scaling of the quantum Fisher information of the initial spin state (including cases exhibiting $N^2$ Heisenberg scaling). Even more surprising, the temporal mode with optimal information content contains a vanishing fraction of the total emitted photons in the large-$N$ limit, suggesting an effective compressing of information. Our results and setup represent a new way to perform cavity based readout of solid-state spin ensembles that allows one to utilize resonant spin-photon interactions.