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利用大气 TOMS 卫星观测资料约束远距离氧化能力

Constraining remote oxidation capacity with ATom observations.

作者信息

Travis Katherine R, Heald Colette L, Allen Hannah M, Apel Eric C, Arnold Stephen R, Blake Donald R, Brune William H, Chen Xin, Commane Róisín, Crounse John D, Daube Bruce C, Diskin Glenn S, Elkins James W, Evans Mathew J, Hall Samuel R, Hintsa Eric J, Hornbrook Rebecca S, Kasibhatla Prasad S, Kim Michelle J, Luo Gan, McKain Kathryn, Millet Dylan B, Moore Fred L, Peischl Jeffrey, Ryerson Thomas B, Sherwen Tomás, Thames Alexander B, Ullmann Kirk, Wang Xuan, Wennberg Paul O, Wolfe Glenn M, Yu Fangqun

机构信息

Department of Civil and Environmental Engineering, Massachusetts Institute of Technology, Cambridge, MA, USA.

Department of Earth, Atmospheric and Planetary Sciences, Massachusetts Institute of Technology, Cambridge, MA, USA.

出版信息

Atmos Chem Phys. 2020 Jul;20(13):7753-7781. doi: 10.5194/acp-20-7753-2020. Epub 2020 Jul 3.

DOI:10.5194/acp-20-7753-2020
PMID:33688335
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7939060/
Abstract

The global oxidation capacity, defined as the tropospheric mean concentration of the hydroxyl radical (OH), controls the lifetime of reactive trace gases in the atmosphere such as methane and carbon monoxide (CO). Models tend to underestimate the methane lifetime and CO concentrations throughout the troposphere, which is consistent with excessive OH. Approximately half of the oxidation of methane and non-methane volatile organic compounds (VOCs) is thought to occur over the oceans where oxidant chemistry has received little validation due to a lack of observational constraints. We use observations from the first two deployments of the NASA ATom aircraft campaign during July-August 2016 and January-February 2017 to evaluate the oxidation capacity over the remote oceans and its representation by the GEOS-Chem chemical transport model. The model successfully simulates the magnitude and vertical profile of remote OH within the measurement uncertainties. Comparisons against the drivers of OH production (water vapor, ozone, and NO concentrations, ozone photolysis frequencies) also show minimal bias, with the exception of wintertime NO . The severe model overestimate of NO during this period may indicate insufficient wet scavenging and/or missing loss on sea-salt aerosols. Large uncertainties in these processes require further study to improve simulated NO partitioning and removal in the troposphere, but preliminary tests suggest that their overall impact could marginally reduce the model bias in tropospheric OH. During the ATom-1 deployment, OH reactivity (OHR) below 3 km is significantly enhanced, and this is not captured by the sum of its measured components (cOHR) or by the model (cOHR). This enhancement could suggest missing reactive VOCs but cannot be explained by a comprehensive simulation of both biotic and abiotic ocean sources of VOCs. Additional sources of VOC reactivity in this region are difficult to reconcile with the full suite of ATom measurement constraints. The model generally reproduces the magnitude and seasonality of cOHR but underestimates the contribution of oxygenated VOCs, mainly acetaldehyde, which is severely underestimated throughout the troposphere despite its calculated lifetime of less than a day. Missing model acetaldehyde in previous studies was attributed to measurement uncertainties that have been largely resolved. Observations of peroxyacetic acid (PAA) provide new support for remote levels of acetaldehyde. The underestimate in both model acetaldehyde and PAA is present throughout the year in both hemispheres and peaks during Northern Hemisphere summer. The addition of ocean sources of VOCs in the model increases cOHR by 3% to 9% and improves model-measurement agreement for acetaldehyde, particularly in winter, but cannot resolve the model summertime bias. Doing so would require 100 Tg yr of a long-lived unknown precursor throughout the year with significant additional emissions in the Northern Hemisphere summer. Improving the model bias for remote acetaldehyde and PAA is unlikely to fully resolve previously reported model global biases in OH and methane lifetime, suggesting that future work should examine the sources and sinks of OH over land.

摘要

全球氧化能力定义为对流层中羟基自由基(OH)的平均浓度,它控制着大气中诸如甲烷和一氧化碳(CO)等活性痕量气体的寿命。模型往往低估了整个对流层中甲烷的寿命和CO浓度,这与过量的OH一致。甲烷和非甲烷挥发性有机化合物(VOCs)的氧化大约有一半被认为发生在海洋上空,由于缺乏观测限制,氧化剂化学在那里几乎没有得到验证。我们利用美国国家航空航天局(NASA)“大气汤勺”(ATom)飞机观测活动在2016年7 - 8月和2017年1 - 2月前两次部署期间的观测数据,来评估偏远海洋上空的氧化能力以及地球化学传输模型(GEOS - Chem)对其的表征。该模型在测量不确定度范围内成功模拟了偏远地区OH的大小和垂直分布。与OH产生的驱动因素(水汽、臭氧和NO浓度、臭氧光解频率)的比较也显示偏差极小,但冬季的NO除外。在此期间模型对NO的严重高估可能表明湿清除不足和/或海盐气溶胶上的损失缺失。这些过程中的巨大不确定性需要进一步研究,以改善对流层中模拟的NO分配和去除,但初步测试表明,它们的总体影响可能会略微降低对流层OH的模型偏差。在“大气汤勺 - 1”(ATom - 1)部署期间,3千米以下的OH反应性(OHR)显著增强,这在其测量组分的总和(cOHR)或模型(cOHR)中均未体现。这种增强可能意味着存在缺失的活性VOCs,但无法通过对生物和非生物海洋VOCs源的全面模拟来解释。该区域VOC反应性的其他来源难以与“大气汤勺”(ATom)的全套测量限制相协调。该模型一般能再现cOHR的大小和季节性,但低估了氧化型VOCs的贡献,主要是乙醛,尽管其计算寿命不到一天,但在整个对流层中都被严重低估。以往研究中模型中乙醛的缺失归因于测量不确定度,而这些不确定度已基本得到解决。过氧乙酸(PAA)的观测为偏远地区的乙醛水平提供了新的支持。模型中乙醛和PAA的低估在两个半球全年都存在,并在北半球夏季达到峰值。在模型中添加海洋VOCs源使cOHR增加了3%至9%,并改善了模型与乙醛测量值的一致性,特别是在冬季,但无法解决模型在夏季的偏差。要做到这一点,全年需要100太克/年的一种寿命长的未知前体,且在北半球夏季有大量额外排放。改善偏远地区乙醛和PAA的模型偏差不太可能完全解决先前报道的模型在OH和甲烷寿命方面的全球偏差,这表明未来的工作应研究陆地上OH的源和汇。

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