A portable instrument for measurement of atmospheric Ox and NO2 based on cavity ring-down spectroscopy

IF 2.3 4区 地球科学 Q3 METEOROLOGY & ATMOSPHERIC SCIENCES Atmospheric and Oceanic Science Letters Pub Date : 2024-11-01 DOI:10.1016/j.aosl.2024.100493
Jinzhao Tong , Renzhi Hu , Changjin Hu , Haotian Cai , Chuan Lin , Jiawei Wang , Liang Chen , Pinhua Xie
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Abstract

Atmospheric Ox (nitrogen dioxide (NO2) + ozone (O3)) can better reflect the local and regional change characteristics of oxidants compared to O3 alone, so obtaining Ox accurately and rapidly is the basis for evaluating the O3 production rate. Furthermore, Ox has proved to be a more representative indicator and can serve as a reflection of pollution prevention efficacy. A portable instrument for measuring atmospheric Ox and NO2 based on cavity ring-down spectroscopy (Ox/NO2-CRDS) was developed in this work. The NO2 concentration is accurately measured according to its absorption characteristic at 407.86 nm. Ambient O3 is converted into NO2 by chemical titration of high concentrations of nitrogen oxide (NO), and the O3 conversion efficiencies obtained are nearly 99%. The detection limit of the Ox/NO2-CRDS system for Ox is 0.024 ppbv (0.1 s), and the overall uncertainty of the instrument is ± 6%. Moreover, the Kalman filtering technique was applied to improve the measurement accuracy of Ox/NO2-CRDS. The system was applied in a comprehensive field observation campaign at Hefei Science Island from 26 to 30 September 2022, and the time concentration series and change characteristics of Ox and NO2 were obtained for five days. The measured Ox concentrations were compared with those of two commercial instruments, and the consistency was good (R2 = 0.98), indicating that this system can be deployed to accurately and rapidly obtain the concentrations of atmospheric Ox and NO2. It will be a useful tool for assessing the atmospheric oxidation capacity and controlling O3 pollution.
摘要
大气Ox (二氧化氮(NO2)+臭氧(O3))相比于O3能够更好的反应区域氧化剂的变化特征, Ox也是反应大气污染防治效果的一个关键指标. 本研究基于腔衰荡光谱技术研发了一套大气Ox和NO2同步测量系统 (Ox/NO2-CRDS). NO2浓度是利用其在407.86 nm处的特征吸收获取, 环境大气的O3通过高浓度的NO被转化为NO2进行间接测量, O3转化效率高于99%, Ox/NO2-CRDS的系统探测限为0.024 ppbv (0.1 s), 系统总不确定度为± 6%. 该Ox/NO2-CRDS系统成功应用于2022年9月26日–30日的合肥市科学岛综合外场观测中, 获取了连续5天的NO2和Ox的时间浓度序列和变化特征, 并将Ox的测量结果与商业化的设备进行了对比验证, 二者具有较好的一致性 (R2 = 0.98), 表明Ox/NO2-CRDS能够被应用于大气Ox和NO2的高灵敏探测. 未来该系统也将会变成评估大气氧化性以及控制臭氧污染的重要工具.

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基于空腔环降光谱的大气 OX 和 NO2 便携式测量仪器
与单独的 O3 相比,大气 Ox(二氧化氮(NO2)+臭氧(O3))能更好地反映氧化剂的局地和区域变化特征,因此准确、快速地获取 Ox 是评价 O3 生成速率的基础。此外,事实证明 Ox 是一个更具代表性的指标,可以作为污染防治效果的反映。本研究开发了一种基于空腔降环光谱(Ox/NO2-CRDS)的便携式大气 Ox 和 NO2 测量仪器。根据二氧化氮在 407.86 纳米波长处的吸收特性,可精确测量二氧化氮的浓度。通过化学滴定高浓度的氧化氮(NO),可将环境中的 O3 转化为 NO2,所获得的 O3 转化效率接近 99%。Ox/NO2-CRDS 系统对 Ox 的检测限为 0.024 ppbv (0.1 s),仪器的总体不确定性为 ± 6%。此外,卡尔曼滤波技术的应用提高了 Ox/NO2-CRDS 的测量精度。该系统于 2022 年 9 月 26 日至 30 日在合肥科学岛进行了一次综合野外观测活动,获得了 Ox 和 NO2 五天的时间浓度序列和变化特征。所测得的 Ox 浓度与两台商业仪器所测得的 Ox 浓度进行了比较,一致性良好(R2 = 0.98),表明该系统可用于准确、快速地获取大气中 Ox 和 NO2 的浓度。摘要大气氧化(二氧化氮(NO2)+臭氧(O3))相比于 O3 能够更好的反应区域氧化剂的变化特征,Ox 也是反应大气污染防治效果的一个关键指标。本研究基于腔衰荡光谱技术研发了一套大气Ox和NO2同步测量系统(Ox/NO2-CRDS)。NO2 浓度是利用其在 407.86 nm 处的特征吸收获取, 环境大气的 O3 通过高浓度的 NO 被转化为 NO2 进行间接测量,O3 转化效率高于 99%,Ox/NO2-CRDS 的系统探测限为 0.024 ppbv (0.1 s),系统总不确定度为± 6%。该 Ox/NO2-CRDS系统成功应用于2022年9月26日-30日的合肥市科学岛综合外场观测中, 获取了连续5天的NO2和Ox的时间浓度序列和变化特征, 并将Ox的测量结果与商业化的设备进行了对比验证, 二者具有较好的一致性 (R2 = 0.98), 表明Ox/NO2-CRDS能够被应用于大气Ox和NO2的高灵敏探测。未来该系统也将会变成评估大气氧化性以及控制臭氧污染的重要工具。
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来源期刊
Atmospheric and Oceanic Science Letters
Atmospheric and Oceanic Science Letters METEOROLOGY & ATMOSPHERIC SCIENCES-
CiteScore
4.20
自引率
8.70%
发文量
925
审稿时长
12 weeks
期刊最新文献
Implications of the extremely hot summer of 2022 on urban ozone control in China Impacts of global biogenic isoprene emissions on surface ozone during 2000–2019 Enhanced nitrous acid (HONO) formation via NO2 uptake and its potential contribution to heavy haze formation during wintertime A portable instrument for measurement of atmospheric Ox and NO2 based on cavity ring-down spectroscopy Vertical distributions of VOCs in the Tibetan Plateau background region
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