亚马逊植被火灾产生的二次超细粒子的密集形成及其对深层云和降水的促进作用

IF 15.1 1区 环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES
Manish Shrivastava, Jiwen Fan, Yuwei Zhang, Quazi Z. Rasool, Bin Zhao, Jiewen Shen, Jeffrey R. Pierce, Shantanu H. Jathar, Ali Akherati, Jie Zhang, Rahul A. Zaveri, Brian Gaudet, Ying Liu, Meinrat O. Andreae, Mira L. Pöhlker, Neil M. Donahue, Yuan Wang, John H. Seinfeld
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引用次数: 0

摘要

人们认为火灾烟雾中不可能形成新颗粒(NPF),因为大量的凝结和凝结汇会清除分子团块。我们分析了飞机在亚马逊上空的测量结果,发现与以前的认识相反,与背景条件相比,火灾大大增加了新粒子和超细粒子(UFP < 直径 50 nm)的数量。我们发现,二甲胺与硫酸的成核作用,在生物质燃烧烟雾中形成的极低挥发性有机物的帮助下,可以克服巨大的冷凝和凝结汇,并解释飞机观测到的现象。我们的研究表明,通过生物质燃烧形成的二次有机气溶胶,新形成的气团迅速长大到 UFP 尺寸,导致 UFP 数量浓度增加了 10 倍。我们发现,在本文研究的案例中,与一次排放产生的较大颗粒相比,UFP 对深对流云的影响截然不同。由于冷凝加热的增加,UFP 增强了深对流云和降水,而较大的颗粒则延迟和减少了降水。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Intense formation of secondary ultrafine particles from Amazonian vegetation fires and their invigoration of deep clouds and precipitation

Intense formation of secondary ultrafine particles from Amazonian vegetation fires and their invigoration of deep clouds and precipitation

New particle formation (NPF) in fire smoke is thought to be unlikely due to large condensation and coagulation sinks that scavenge molecular clusters. We analyze aircraft measurements over the Amazon and find that fires significantly enhance NPF and ultrafine particle (UFP < 50 nm diameter) numbers compared to background conditions, contrary to previous understanding. We identify that the nucleation of dimethylamine with sulfuric acid, which is aided by the formation of extremely low volatility organics in biomass-burning smoke, can overcome the large condensation and coagulation sinks and explain aircraft observations. We show that freshly formed clusters rapidly grow to UFP sizes through biomass-burning secondary organic aerosol formation, leading to a 10-fold increase in UFP number concentrations. We find a contrasting effect of UFPs on deep convective clouds compared to the larger particles from primary emissions for the case investigated here. UFPs intensify the deep convective clouds and precipitation due to increased condensational heating, while larger particles delay and reduce precipitation.

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来源期刊
One Earth
One Earth Environmental Science-Environmental Science (all)
CiteScore
18.90
自引率
1.90%
发文量
159
期刊介绍: One Earth, Cell Press' flagship sustainability journal, serves as a platform for high-quality research and perspectives that contribute to a deeper understanding and resolution of contemporary sustainability challenges. With monthly thematic issues, the journal aims to bridge gaps between natural, social, and applied sciences, along with the humanities. One Earth fosters the cross-pollination of ideas, inspiring transformative research to address the complexities of sustainability.
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