Towards automated inclusion of autoxidation chemistry in models: from precursors to atmospheric implications

Lukas Pichelstorfer; Pontus Roldin; Matti Rissanen; Noora Hyttinen; Olga Garmash; Carlton Xavier; Putian Zhou; Petri Clusius; Benjamin Foreback; Thomas Golin Almeida; Chenjuan Deng; Metin Baykara; Theo Kurten; Michael Boy

doi:10.1039/d4ea00054d

Towards automated inclusion of autoxidation chemistry in models: from precursors to atmospheric implications

Lukas Pichelstorfer, Pontus Roldin, Matti Rissanen, Noora Hyttinen, Olga Garmash, Carlton Xavier, Putian Zhou, Petri Clusius, Benjamin Foreback, Thomas Golin Almeida, Chenjuan Deng, Metin Baykara, Theo Kurten, Michael Boy

Physics

Research output: Contribution to journal › Article › Scientific › peer-review

6 Downloads (Pure)

Abstract

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-NO_x 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.

Original language	English
Pages (from-to)	879-896
Number of pages	18
Journal	Environmental science: atmospheres
Issue number	8
DOIs	https://doi.org/10.1039/d4ea00054d
Publication status	Published - 2024
Publication type	A1 Journal article-refereed

Publication forum classification

Publication forum level 1

ASJC Scopus subject areas

Analytical Chemistry
Chemistry (miscellaneous)
Environmental Chemistry
Pollution

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1039/d4ea00054dLicence: CC BY

d4ea00054dFinal published version, 2.1 MBLicence: CC BY

https://urn.fi/URN:NBN:fi:tuni-202408098024Licence: CC BY

Cite this

Pichelstorfer, L., Roldin, P., Rissanen, M., Hyttinen, N., Garmash, O., Xavier, C., Zhou, P., Clusius, P., Foreback, B., Golin Almeida, T., Deng, C., Baykara, M., Kurten, T., & Boy, M. (2024). Towards automated inclusion of autoxidation chemistry in models: from precursors to atmospheric implications. Environmental science: atmospheres, (8), 879-896. https://doi.org/10.1039/d4ea00054d

@article{983c621cbc2e4a2aa260d862e3c2cb04,

title = "Towards automated inclusion of autoxidation chemistry in models: from precursors to atmospheric implications",

abstract = "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.",

author = "Lukas Pichelstorfer and Pontus Roldin and Matti Rissanen and Noora Hyttinen and Olga Garmash and Carlton Xavier and Putian Zhou and Petri Clusius and Benjamin Foreback and {Golin Almeida}, Thomas and Chenjuan Deng and Metin Baykara and Theo Kurten and Michael Boy",

note = "Publisher Copyright: {\textcopyright} 2024 RSC.",

year = "2024",

doi = "10.1039/d4ea00054d",

language = "English",

pages = "879--896",

number = "8",

}

Pichelstorfer, L, Roldin, P, Rissanen, M, Hyttinen, N, Garmash, O, Xavier, C, Zhou, P, Clusius, P, Foreback, B, Golin Almeida, T, Deng, C, Baykara, M, Kurten, T & Boy, M 2024, 'Towards automated inclusion of autoxidation chemistry in models: from precursors to atmospheric implications', Environmental science: atmospheres, no. 8, pp. 879-896. https://doi.org/10.1039/d4ea00054d

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

AU - Foreback, Benjamin

AU - Golin Almeida, Thomas

AU - Deng, Chenjuan

AU - Baykara, Metin

AU - Kurten, Theo

AU - Boy, Michael

PY - 2024

Y1 - 2024

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.

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.

U2 - 10.1039/d4ea00054d

DO - 10.1039/d4ea00054d

M3 - Article

AN - SCOPUS:85198941130

SN - 2634-3606

SP - 879

EP - 896

JO - Environmental science: atmospheres

JF - Environmental science: atmospheres

IS - 8

ER -

Towards automated inclusion of autoxidation chemistry in models: from precursors to atmospheric implications

Abstract

Publication forum classification

ASJC Scopus subject areas

UN SDGs

Access to Document

Fingerprint

Cite this