We show that detection of single photons is not subject to the fundamental limitations that accompany quantum linear amplification of bosonic mode amplitudes, even though a photodetector does amplify a few-photon input signal to a macroscopic output signal. Alternative limits are derived for \emph{nonlinear} photon-number amplification schemes with optimistic implications for single-photon detection. Four commutator-preserving transformations are presented: one idealized (which is optimal) and three more realistic (less than optimal). Our description makes clear that nonlinear amplification takes place, in general, at a different frequency ω′ than the frequency ω of the input photons. This can be exploited to suppress thermal noise even further up to a fundamental limit imposed by amplification into a single bosonic mode. A practical example that fits our description very well is electron-shelving.
@article{arxiv.1809.02195,
title = {On Nonlinear Amplification: Improved Quantum Limits for Photon Counting},
author = {Tzula B. Propp and S. J. van Enk},
journal= {arXiv preprint arXiv:1809.02195},
year = {2019}
}