English

Mode-programmable comb spectroscopy enabling non-cooperative computational sensing with single-photon sensitivity

Optics 2025-11-21 v1 Applied Physics

Abstract

Frequency comb spectroscopy provides broadband access to molecular fingerprints with mode-defined spectral resolution. However, its deployment in non-cooperative gas sensing remains challenging because conventional implementations require cooperative reflectors or well-controlled optical returns. Here, we overcome this limitation by introducing a computational sensing scheme based on a mode-programmable optical comb and a high-sensitivity single-pixel detector. In our approach, a two-dimensional disperser and a high-speed digital micromirror device encode individual comb modes, enabling broadband, mode-resolved spectral acquisition without relying on coherent detection. This architecture supports measurements through highly scattering media and from non-cooperative targets while retaining the core advantages of frequency-comb spectroscopy. Our method achieves picometer-level spectral resolution, a 10-nm (1.27-THz) instantaneous bandwidth, single-photon sensitivity down to 10^-4 photons per pulse, and compressed spectral acquisition with 2.5% sampling for <10% reconstruction error. These capabilities establish a powerful platform for diverse gas-sensing applications, including remote environmental monitoring, industrial leak localization, and explosive-threat detection.

Keywords

Cite

@article{arxiv.2511.16365,
  title  = {Mode-programmable comb spectroscopy enabling non-cooperative computational sensing with single-photon sensitivity},
  author = {Dongxu Zhu and Zhuoren Wan and Xiaoshuai Ma and Ming Yan and Yuan Chen and Mei Yang and Zijian Wang and Xiuxiu Zhang and Min Li and Hua Li and Kun Huang and Yan Liang and Heping Zeng},
  journal= {arXiv preprint arXiv:2511.16365},
  year   = {2025}
}

Comments

20 pages, 6 figures

R2 v1 2026-07-01T07:47:16.138Z