Controlling Biogenic Particle Mass with NOx and SOx.

EM (Pittsburgh, Pa.) Pub Date : 2019-05-01
Annmarie G Carlton, Sherri W Hunt
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Abstract

Models that accurately predict atmospheric composition and correctly respond to tested policy scenarios aid air quality managers in the development of effective strategies to protect human health. Controllable emissions from human activity interact with natural emissions from plants and trees from the biosphere through complex chemistry to form ozone (O3) and organic fine particulate matter (PM2.5), criteria air pollutants that induce a variety of adverse health effects. While organic gases emitted from plants and trees are natural, some fraction of the subsequent O3 and PM2.5 is not. Accurate assessment of the extent to which human activity and natural emissions interact to form pollution can be achieved when models are constructed from first principle chemical and physical laws, and tested and evaluated with laboratory and field observations. In the summer of 2013, hundreds of scientists descended on the southeast U.S. to coordinate an atmospheric chemistry campaign with the ultimate goal of understanding complex biosphere-atmosphere interactions, the subsequent formation of O3 and PM2.5, and accurate incorporation of the chemistry into atmospheric models. A main finding from the campaign is that anthropogenic emissions facilitate formation of organic PM2.5 derived from biogenic VOCs. This fraction of PM2.5 is controllable pollution. Mechanistic insight from that campaign was recently incorporated into EPA's air quality model, improving the model representation of the atmospheric modeling and informing air quality management strategies for PM2.5. Emission reductions in SO2 and NOx in the southeast U.S. are found to reduce non-fossil, presumably biogenic, organic PM2.5 mass concentrations, suggesting existing Federal rules have been more successful than anticipated. Additional potential feedback mechanisms may become important as emissions reductions bring the atmosphere into new chemical regimes.

利用NOx和SOx控制生物源粒子质量。
准确预测大气成分并对经过测试的政策情景作出正确反应的模型有助于空气质量管理人员制定保护人类健康的有效战略。来自人类活动的可控排放与来自生物圈的植物和树木的自然排放通过复杂的化学反应相互作用,形成臭氧(O3)和有机细颗粒物(PM2.5),这是诱发各种不利健康影响的标准空气污染物。虽然植物和树木排放的有机气体是自然的,但随后的O3和PM2.5的一部分不是。要准确评估人类活动和自然排放相互作用形成污染的程度,可以根据第一线化学和物理定律构建模型,并通过实验室和实地观察进行检验和评价。2013年夏天,数百名科学家来到美国东南部,协调一项大气化学运动,其最终目标是了解复杂的生物圈-大气相互作用,O3和PM2.5的后续形成,并将化学成分准确地纳入大气模型。该运动的一个主要发现是,人为排放促进了生物源性voc衍生的有机PM2.5的形成。这部分PM2.5属于可控污染。最近,从该运动中获得的机制见解被纳入了EPA的空气质量模型,改善了大气模型的模型表示,并为PM2.5的空气质量管理策略提供了信息。研究发现,在美国东南部减少二氧化硫和氮氧化物的排放,可以降低非化石(可能是生物源)有机PM2.5的质量浓度,这表明现有的联邦法规比预期的要成功。其他潜在的反馈机制可能变得重要,因为减排使大气进入新的化学体制。
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