Austin C. Flueckiger, Christopher N. Snyder, Giuseppe A. Petrucci
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引用次数: 0
摘要
相对湿度(RH)对臭氧分解生物源性挥发性有机化合物(BVOCs)形成有机新粒子(NPF)的影响仍然是一个活跃的争论领域。以前的报告提供了相互矛盾的结果,表明在高RH条件下NPF既有抑制又有增强。本文报道了RH对植被释放的绿叶挥发物(GLV)顺-3-己烯乙酸酯(CHA)的暗臭氧分解对NPF的影响。我们发现RH通过BVOC抑制NPF,基本上在RH水平下将其关闭。1%。虽然抑制NPF的机制尚不清楚,但我们证明这可能不是由于CHA在潮湿腔壁上的损失增加。根据估计的蒸汽压(VPs),提出了在潮湿条件下占主导地位的新氧化产物,应增强NPF;然而,这些低挥发性产物的气相浓度可能不足以引发NPF。此外,c3 -激发态Criegee中间体(CIs)与水的反应可能导致形成不参与NPF的小羧酸。这一假设得到了季O3 + CHA + α-蒎烯+ RH体系实验的支持,结果表明,在~0% RH时,总α-蒎烯衍生的NPF减少,随后在升高RH时恢复。
Nontrivial Impact of Relative Humidity on Organic New Particle Formation from Ozonolysis of cis-3-Hexenyl Acetate
The impact of relative humidity (RH) on organic new particle formation (NPF) from the ozonolysis of biogenic volatile organic compounds (BVOCs) remains an area of active debate. Previous reports provide contradictory results, indicating both the depression and enhancement of NPF under conditions of high RH. Herein, we report on the impact of RH on NPF from the dark ozonolysis of cis-3-hexenyl acetate (CHA), a green-leaf volatile (GLV) emitted by vegetation. We show that RH inhibits NPF by this BVOC, essentially shutting it down at RH levels > 1%. While the mechanism for the inhibition of NPF remains unclear, we demonstrate that it is likely not due to increased losses of CHA to the humid chamber walls. New oxidation products dominant under humid conditions are proposed that, based on estimated vapor pressures (VPs), should enhance NPF; however, it is possible that the vapor phase concentration of these low-volatility products is not sufficient to initiate NPF. Furthermore, the reaction of C3-excited state Criegee intermediates (CIs) with water may lead to the formation of small carboxylic acids that do not contribute to NPF. This hypothesis is supported by experiments with quaternary O3 + CHA + α-pinene + RH systems, which showed decreases in total α-pinene-derived NPF at ~0% RH and subsequent recovery at elevated RH.
期刊介绍:
The quality of the environment within buildings is a topic of major importance for public health.
Indoor Air provides a location for reporting original research results in the broad area defined by the indoor environment of non-industrial buildings. An international journal with multidisciplinary content, Indoor Air publishes papers reflecting the broad categories of interest in this field: health effects; thermal comfort; monitoring and modelling; source characterization; ventilation and other environmental control techniques.
The research results present the basic information to allow designers, building owners, and operators to provide a healthy and comfortable environment for building occupants, as well as giving medical practitioners information on how to deal with illnesses related to the indoor environment.
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