A systematic review of reactive nitrogen simulations with chemical transport models in China

IF 4.5 2区地球科学 Q1 METEOROLOGY & ATMOSPHERIC SCIENCES

Atmospheric Research Pub Date : 2024-07-14 DOI:10.1016/j.atmosres.2024.107586

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引用次数: 0

Abstract

As primary emissions have been declining in recent decades in China, secondary pollution, like ozone (O₃) and secondary aerosols are main pollutants deteriorating air quality. The chemistry of reactive nitrogen (Nr) plays a crucial role in the chemical transformation of secondary aerosols and O₃, and its representation in three-dimensional (3-D) regional/global chemical transport models is vital for quantitatively understanding Nr's role in air pollution as well as future emission control. This study reviews the parameterizations of the Nr modeling in chemical transport models (CTMs) and their environmental implications over the past decade in China. A number of Nr species are present in the atmosphere. Given the significant impact of Nr on air quality, we have identified four research topics within the broader field of Nr research. These Nr topics include the multiphase chemistry of inorganic nitrates (which involves NO, NO₂, NH₃, HNO₃, NO₃ radicals, N₂O₅, ClNO₂ and nitrate), organic nitrates (which involves NO, NO₃, RONO₂ and HNO₃), HONO (which involves NO, NO₂, HONO, and nitrate), and reduced‑nitrogen (which involves NH₃ and amines). Regional CTM modeling of inorganic nitrates mainly focuses on homogeneous NO₂ oxidation and heterogeneous N₂O₅ hydrolysis, which contribute to over 80% of inorganic nitrate formation in China. During hazy days, the contribution of heterogeneous uptake of N₂O₅ can be amplified. By contrast, organic nitrates modeling, including their gas-phase reactions, gas-particle conversion, and hydrolysis, is poorly explored in China, despite their importance for secondary organic aerosol (SOA) formation. HONO sources and their impacts on atmospheric oxidizing capacity (AOC) are an emerging research topic. Parameterizations of major HONO sources were presented, including the homogeneous pathway, direct emissions, heterogeneous uptake of NO₂ on solid surfaces, and nitrate photolysis. The heterogeneous uptake of NO₂ is the predominant pathway of HONO formation. HONO affects AOC by regulating the OH budget, particularly during the early morning when O₃ photochemistry is not efficient. For NH₃ and amines, current CTMs fail to accurately represent their sources in urban regions due to the lack of non-agricultural emissions. Although amines do not significantly influence chemical cycles, they show strong potential in inducing new particle formation. Overall, further work is needed to improve Nr modeling in China by developing parameterizations suitable for the Chinese atmospheric conditions, establishing accurate sector-based emission inventories for NH₃ and amines, and realizing effective modeling of organic nitrates in the future.

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中国利用化学迁移模型模拟活性氮的系统回顾

近几十年来，中国的一次排放不断减少，臭氧（O3）和二次气溶胶等二次污染成为恶化空气质量的主要污染物。活性氮（Nr）的化学性质在二次气溶胶和臭氧的化学转化过程中起着至关重要的作用，在三维（3-D）区域/全球化学传输模型中表示活性氮对于定量了解 Nr 在空气污染中的作用以及未来的排放控制至关重要。本研究回顾了中国近十年来在化学传输模式（CTMs）中对 Nr 建模的参数设置及其对环境的影响。大气中存在多种 Nr。鉴于 Nr 对空气质量的重大影响，我们在更广泛的 Nr 研究领域确定了四个研究课题。这些 Nr 主题包括无机硝酸盐（涉及 NO、NO2、NH3、HNO3、NO3 自由基、N2O5、ClNO2 和硝酸盐）、有机硝酸盐（涉及 NO、NO3、RONO2 和 HNO3）、HONO（涉及 NO、NO2、HONO 和硝酸盐）和还原氮（涉及 NH3 和胺）的多相化学。无机硝酸盐的区域 CTM 建模主要集中在均相 NO2 氧化和异相 N2O5 水解，这两种氧化和水解作用占中国无机硝酸盐形成的 80% 以上。在雾霾天，N2O5 的异相吸收作用会被放大。相比之下，尽管有机硝酸盐对二次有机气溶胶（SOA）的形成非常重要，但中国对其气相反应、气体-粒子转化和水解等有机硝酸盐模型的研究却很少。HONO 来源及其对大气氧化能力（AOC）的影响是一个新兴的研究课题。本文介绍了主要 HONO 源的参数设置，包括均相途径、直接排放、固体表面对 NO2 的异相吸收以及硝酸盐光解。NO2 的异相吸收是 HONO 形成的主要途径。HONO 通过调节 OH 预算来影响 AOC，尤其是在 O3 光化学效率不高的清晨。至于 NH3 和胺，由于缺乏非农业排放，目前的 CTM 无法准确反映其在城市地区的来源。尽管胺类物质对化学循环的影响不大，但它们在诱导新粒子形成方面显示出强大的潜力。总之，要改进中国的 Nr 建模，还需要进一步开展工作，开发适合中国大气条件的参数，建立准确的基于部门的 NH3 和胺排放清单，并在未来实现对有机硝酸盐的有效建模。

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来源期刊

Atmospheric Research 地学-气象与大气科学

CiteScore

9.40

自引率

10.90%

发文量

460

审稿时长

47 days

期刊介绍： The journal publishes scientific papers (research papers, review articles, letters and notes) dealing with the part of the atmosphere where meteorological events occur. Attention is given to all processes extending from the earth surface to the tropopause, but special emphasis continues to be devoted to the physics of clouds, mesoscale meteorology and air pollution, i.e. atmospheric aerosols; microphysical processes; cloud dynamics and thermodynamics; numerical simulation, climatology, climate change and weather modification.