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偏振拉曼光谱测量大气中的痕量氢气OA

Measurement of Trace Hydrogen in Atmosphere Using Polarized Raman Spectroscopy

中文摘要英文摘要

氢气(H2)作为一种清洁能源,在工业等领域的需求日益增长.为了有效监测H2 在生产、储存、运输和使用过程中的泄漏情况,需实时检测大气环境中的痕量H2.然而,痕量H2 的光学检测面临诸多挑战.氢分子仅具有极微弱的电四极矩跃迁,难以通过吸收光谱法进行有效测量;拉曼光谱虽在痕量气体检测中展现出良好的潜力,但其灵敏度不足.本研究提出了一种结合PDH锁频技术的腔增强拉曼光谱方法,通过测量偏振拉曼光谱,一方面利用腔增强技术大幅提升气体散射信号强度,另一方面借助不同振动模式拉曼峰的偏振特性可分辨性,实现了复杂拉曼光谱的简化,从而消除了H2 测量过程中水汽的干扰.本方法对H2 的检出限(LOD)低至0.06 μmol/mol(1标准大气压下),可实现对环境大气中H2 的直接采样和连续测量,测量相对精度为5%,表明其具有在复杂气体环境中定量测定痕量H2 的能力.

As a clean energy source,the demand for hydrogen gas(H2)in industrial and commercial sectors is growing.To effectively monitor H2 leaks during production,storage,transportation and use,it is necessary to perform real-time detection of trace amounts of H2 in atmospheric conditions.However,the optical detection of trace hydrogen faces significant challenges due to the extremely weak electric quadrupole transitions of hydrogen molecules,making absorption spectroscopy measurements difficult.Raman spectroscopy has great potential for measuring trace gases,but its application is limited by sensitivity.In this work,a cavity-enhanced Raman spectroscopy technique incorporating Pound-Drever-Hall(PDH)frequency locking was presented.By measuring polarized Raman spectra,cavity enhancement significantly amplified the gas scattering signal intensity,and it leveraged the discriminability in polarization characteristics among Raman peaks of different vibrational modes to simplify complex Raman spectra and eliminate interference from water vapor during hydrogen gas measurement.This method achieved a low detection limit of 0.06 μmol/mol(at 1 atm)for hydrogen,enabling direct sampling and continuous measurement of hydrogen in ambient air with a relative measurement precision of 5%,which demonstrated its capability for quantitative measurement of trace H2 in complex gas environments.

宋逸凡;仰青颖;陈胜坦;王进;谈艳;孙羽;胡水明

中国科学技术大学,合肥微尺度物质科学国家研究中心,合肥 230026中国科学技术大学,合肥微尺度物质科学国家研究中心,合肥 230026中国科学技术大学,合肥微尺度物质科学国家研究中心,合肥 230026合肥国家实验室,合肥 230088中国科学技术大学,合肥微尺度物质科学国家研究中心,合肥 230026深圳先进光源研究院,深圳 518107中国科学技术大学,合肥微尺度物质科学国家研究中心,合肥 230026||合肥国家实验室,合肥 230088

光谱学痕量气体检测偏振拉曼光谱腔增强拉曼光谱氢气

SpectroscopyTrace gas detectionPolarized Raman spectroscopyCavity-enhanced Raman spectroscopyHydrogen

《分析化学》 2026 (1)

92-99,8

科技创新2030"量子通信与量子计算机"重大项目(Nos.2021ZD0303102,2023ZD0301000)和国家自然科学基金项目(Nos.22241302,12393825)资助. Supported by the Innovation Program for Quantum Science and Technology(Nos.2021ZD0303102,2023ZD0301000)and the National Natural Science Foundation of China(Nos.22241302,12393825).

10.19756/j.issn.0253-3820.251007

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