Recently, a research team led by Prof. FANG Yonghua from the Hefei Institutes of Physical Science, Chinese Academy of Sciences, proposed and systematically optimized a novel Parabolic Mirror Cavity-Enhanced Raman Spectroscopy (PMCERS) technique, achieving a marked improvement in gas detection sensitivity through the integration of advanced optical design and signal-processing methods.
The research results were published in Optics & Laser Technology.
Multi-component gas detection is important for environmental, industrial, and medical applications. Raman spectroscopy is well suited for this purpose because it enables simultaneous, water-vapor-free detection of multiple gas species. However, its inherently weak scattering limits sensitivity, and conventional cavity-enhanced approaches relying on lens-based collection suffer from limited numerical aperture, resulting in inefficient capture of three-dimensionally distributed Raman signals.
In this study, the team developed a parabolic-mirror-based cavity-enhanced Raman spectroscopy system, leveraging the large-aperture characteristics of parabolic mirrors to significantly improve Raman signal collection. Through systematic optimization of the cavity structure, an efficient closed-loop optical path was established, effectively eliminating signal collection blind spots and suppressing stray-light interference.
In addition, the researchers designed an optimized spectral analysis strategy to reliably extract weak Raman signals from noisy backgrounds under low signal-to-noise conditions. This approach effectively reduces random noise and baseline fluctuations, enabling accurate identification of trace gas components.
Experimental results show that the optimized PMCERS system delivers substantially enhanced signal strength and detection sensitivity compared with conventional cavity-enhanced Raman configurations. At the same time, the gas cavity was significantly miniaturized, demonstrating the technique’s strong potential for compact, high-sensitivity, and practical gas sensing applications.
This work provides a new technical pathway for high-sensitivity and compact gas detection, with promising prospects for practical applications, according to the team.
Schematic diagram of the O-PMCERS system (Image by LI Zhengang)
