TY - JOUR
T1 - Towards automated inclusion of autoxidation chemistry in models
T2 - from precursors to atmospheric implications
AU - Pichelstorfer, Lukas
AU - Roldin, Pontus
AU - Rissanen, Matti
AU - Hyttinen, Noora
AU - Garmash, Olga
AU - Xavier, Carlton
AU - Zhou, Putian
AU - Clusius, Petri Sebastian
AU - Foreback, Benjamin
AU - Golin Almeida, Thomas
AU - Deng, Chenjuan
AU - Baykara, Metin
AU - Kurten, Theo
AU - Boy, Michael
PY - 2024/7/9
Y1 - 2024/7/9
N2 - In the last few decades, atmospheric formation of secondary organic aerosols (SOA) has gained increasing attention due to their impact on air quality and climate. However, methods to predict their abundance are mainly empirical and may fail under real atmospheric conditions. In this work, a close-to-mechanistic approach allowing SOA quantification is presented, with a focus on a chain-like chemical reaction called "autoxidation". A novel framework is employed to (a) describe the gas-phase chemistry, (b) predict the products' molecular structures and (c) explore the contribution of autoxidation chemistry on SOA formation under various conditions. As a proof of concept, the method is applied to benzene, an important anthropogenic SOA precursor. Our results suggest autoxidation to explain up to 100% of the benzene-SOA formed under low-NOx laboratory conditions. Under atmospheric-like day-time conditions, the calculated benzene-aerosol mass continuously forms, as expected based on prior work. Additionally, a prompt increase, driven by the NO3 radical, is predicted by the model at dawn. This increase has not yet been explored experimentally and stresses the potential for atmospheric SOA formation via secondary oxidation of benzene by O3 and NO3
AB - In the last few decades, atmospheric formation of secondary organic aerosols (SOA) has gained increasing attention due to their impact on air quality and climate. However, methods to predict their abundance are mainly empirical and may fail under real atmospheric conditions. In this work, a close-to-mechanistic approach allowing SOA quantification is presented, with a focus on a chain-like chemical reaction called "autoxidation". A novel framework is employed to (a) describe the gas-phase chemistry, (b) predict the products' molecular structures and (c) explore the contribution of autoxidation chemistry on SOA formation under various conditions. As a proof of concept, the method is applied to benzene, an important anthropogenic SOA precursor. Our results suggest autoxidation to explain up to 100% of the benzene-SOA formed under low-NOx laboratory conditions. Under atmospheric-like day-time conditions, the calculated benzene-aerosol mass continuously forms, as expected based on prior work. Additionally, a prompt increase, driven by the NO3 radical, is predicted by the model at dawn. This increase has not yet been explored experimentally and stresses the potential for atmospheric SOA formation via secondary oxidation of benzene by O3 and NO3
KW - 116 Chemical sciences
U2 - 10.1039/d4ea00054d
DO - 10.1039/d4ea00054d
M3 - Article
SN - 2634-3606
VL - 4
SP - 879
EP - 896
JO - Environmental science: Atmospheres
JF - Environmental science: Atmospheres
IS - 8
ER -