CO的第二泛频(3←0)跃迁谱线线形强度测量研究

doi:10.3969/j.issn.1000-1158.2020.12.19

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摘要 CO分子是监测大气污染气体的优异示踪气体,要实现对CO分子实时监控就需要做到对气体浓度的精确快速测量。气体分子浓度测量可以利用测量吸收光谱和谱线线形强度得到,CO的(3←0)泛频谱带是吸收较弱的跃迁波段,利用以干空气为缓冲气体的200μmol/mol的CO混合物,基于稳频的光腔衰荡装置测量了在温度293K、压力13~93kPa下的CO分子R支3条跃迁谱线的吸收光谱。HTP(Hartmann-Tran profile)线形被用来获得这些谱线的线形强度,测量结果的相对标准不确定度优于1%,与国际HITRAN、HITEMP和GEISA光谱数据库比较,相对偏差小于4%。

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	潘金明
	林鸿
	冯晓娟
	宦克为
	张金涛

关键词 ：计量学;一氧化碳浓度;光腔衰荡光谱;线形强度, 大气污染监测

Abstract：CO molecule is an excellent tracer gas for monitoring air pollution. Accurate and fast measurement of gas concentration is required for real-time monitoring of CO molecule. Gas molecule concentration measurements can be obtained by measuring the absorption spectra and the linear intensity of the spectrum. The CO (3←0) universal spectrum band is a transition band with weak absorption. The absorption spectra of three R branch transition spectra of CO molecule are measured at a temperature of 293K and pressures of 13~93kPa by using a frequency-stable optical cavity ring-down device with 200μmol/mol CO mixture using dry air as buffer gas, and HTP (Hartmann-Tran profile) lines are used to obtain the linear intensity of these lines. The relative standard uncertainty for line intensity measurement is less than 1%, and compared with the international HITRAN, HITEMP and GEISA spectral databases, the relative deviation is less than 4%.

Key words： metrology carbon monoxide concentration cavity ring-down spectroscopy line intensities air pollution monitoring

收稿日期: 2020-03-16 发布日期: 2020-12-08

PACS:	TB99
	TB96

基金资助:国家国际科技合作专项(2015DFG71880);国家自然科学基金(51476153)

作者简介: 潘金明(1993-),男,吉林蛟河人,长春理工大学硕士研究生,主要研究方向为红外光学与系统。Email: pan1851205@163.com

引用本文:

潘金明,林鸿,冯晓娟,宦克为,张金涛. CO的第二泛频(3←0)跃迁谱线线形强度测量研究[J]. 计量学报, 2020, 41(12): 1565-1569.
PAN Jin-ming,LIN Hong,FENG Xiao-juan,HUAN Ke-wei,ZHANG Jin-tao. Investigation on the Line Intensity Measurement of the Second Overtone (3←0) Band of CO. Acta Metrologica Sinica, 2020, 41(12): 1565-1569.

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