English

Multi-Mode Array Filtering of Resonance Fluorescence

Quantum Physics 2024-08-20 v4

Abstract

We present a novel frequency-filtering method for measuring and calculating frequency-filtered photon-correlations. This novel method is a cavity-based system we call the multi-mode array filter, which consists of an array of tunable single-mode cavities that are equally spaced in frequency. By introducing a mode-dependent phase modulation, we produce a near rectangular frequency response, allowing us to increase the filter bandwidth -- and thus the temporal response -- without sacrificing frequency isolation. We model the frequency filtering using a cascaded quantum open systems approach which completely neglects any back-action of the filter onto the source system. This allows us to derive a closed set of operator moment equations for source and filter system operators, thus providing an extremely efficient method to calculate frequency-filtered first- and second-order correlation functions. We demonstrate this novel filtering method by applying it to a resonantly driven two-level atom. We present examples of frequency-filtered power spectra to demonstrate the improved frequency isolation of the multi-mode array filter over the single-mode filter. We then present results for the single-mode and multi-mode-array filtered second-order auto- and cross-correlation functions. These are compared against expressions derived in the secular approximation. The improved frequency isolation of the multi-mode array filter allows us to investigate new regimes of frequency-filtered photon correlations, such as two-photon leapfrog processes, and the effect of vanishing bandwidth on filtered auto-correlation functions.

Keywords

Cite

@article{arxiv.2405.03900,
  title  = {Multi-Mode Array Filtering of Resonance Fluorescence},
  author = {Jacob Ngaha and Scott Parkins and Howard J. Carmichael},
  journal= {arXiv preprint arXiv:2405.03900},
  year   = {2024}
}

Comments

21 pages, 15 figures

R2 v1 2026-06-28T16:18:47.972Z