Enhancement of broadband entangled two-photon absorption by resonant spectral phase flips

TL;DR

This paper demonstrates that applying a resonant spectral phase flip to broadband entangled photons significantly enhances two-photon absorption rates, enabling improved phase-sensitive spectroscopy especially at challenging low-energy spectra.

Contribution

It introduces a novel spectral phase flip technique to optimize two-photon absorption in broadband entangled photons, revealing resonances and enhancing TPA rates.

Findings

Resonant phase flips maximize TPA enhancement at intermediate resonances.

The enhancement is strongest when the resonance frequency difference exceeds the resonance linewidth.

Spectral phase flips enable phase-sensitive spectroscopy at low photon energies.

Abstract

Broadband energy-time entanglement can be used to enhance the rate of two-photon absorption (TPA) by combining a precise two-photon resonance with a very short coincidence time. Because of this short coincidence time, broadband TPA is not sensitive to the spectrum of intermediate levels, making it the optimal choice when the intermediate transitions are entirely virtual. In the case of distinct intermediate resonances, it is possible to enhance TPA by introducing a phase dispersion that matches the intermediate resonances. Here, we consider the effects of a phase flip in the single photon spectrum, where the phases of all frequencies above a certain frequency are shifted by half a wavelength relative to the frequencies below this frequency. The frequency at which the phase is flipped can then be scanned to reveal the position of intermediate resonances. We find that a resonant phase flip maximizes the contributions of the asymmetric imaginary part of the dispersion that characterizes a typical resonance, resulting in a considerable enhancement of the TPA rate. Due to the bosonic symmetry of TPA, the enhancement is strongest when the resonance occurs when the frequency difference of the two photons is much higher than the linewidth of the resonance. Our results indicate that broadband entangled TPA with spectral phase flips may be suitable for phase-sensitive spectroscopy at the lower end of the spectrum where direct photon detection is difficult.