Microphysical explanation of the RH-dependent water affinity of biogenic organic aerosol and its importance for climate

N. Rastak; A. Pajunoja; J. C. Acosta Navarro; J. Ma; M. Song; D. G. Partridge; A. Kirkevåg; Y. Leong; W. W. Hu; N. F. Taylor; A. Lambe; K. Cerully; A. Bougiatioti; P. Liu; R. Krejci; T. Petäjä; C. Percival; P. Davidovits; D. R. Worsnop; A. M.L. Ekman; A. Nenes; S. Martin; J. L. Jimenez; D. R. Collins; D. O. Topping; A. K. Bertram; A. Zuend; A. Virtanen; I. Riipinen

doi:10.1002/2017GL073056

Microphysical explanation of the RH-dependent water affinity of biogenic organic aerosol and its importance for climate

N. Rastak
, A. Pajunoja
, J. C. Acosta Navarro
, J. Ma
, M. Song
, D. G. Partridge
, A. Kirkevåg
, Y. Leong
, W. W. Hu
, N. F. Taylor
, A. Lambe
, K. Cerully
, A. Bougiatioti
, P. Liu
, R. Krejci
, T. Petäjä
, C. Percival
, P. Davidovits
, D. R. Worsnop
, A. M.L. Ekman

A. Nenes, S. Martin, J. L. Jimenez, D. R. Collins, D. O. Topping, A. K. Bertram, A. Zuend, A. Virtanen, I. Riipinen^*

^*Corresponding author for this work

Department of Earth and Environmental Sciences

Research output: Contribution to journal › Journal article › peer-review

83 Scopus citations

Abstract

A large fraction of atmospheric organic aerosol (OA) originates from natural emissions that are oxidized in the atmosphere to form secondary organic aerosol (SOA). Isoprene (IP) and monoterpenes (MT) are the most important precursors of SOA originating from forests. The climate impacts from OA are currently estimated through parameterizations of water uptake that drastically simplify the complexity of OA. We combine laboratory experiments, thermodynamic modeling, field observations, and climate modeling to (1) explain the molecular mechanisms behind RH-dependent SOA water-uptake with solubility and phase separation; (2) show that laboratory data on IP- and MT-SOA hygroscopicity are representative of ambient data with corresponding OA source profiles; and (3) demonstrate the sensitivity of the modeled aerosol climate effect to assumed OA water affinity. We conclude that the commonly used single-parameter hygroscopicity framework can introduce significant error when quantifying the climate effects of organic aerosol. The results highlight the need for better constraints on the overall global OA mass loadings and its molecular composition, including currently underexplored anthropogenic and marine OA sources.

Original language	English
Pages (from-to)	5167-5177
Number of pages	11
Journal	Geophysical Research Letters
Volume	44
Issue number	10
DOIs	https://doi.org/10.1002/2017GL073056
State	Published - 2017.05.28

Keywords

aerosol-climate interactions
aerosol-water interactions
atmospheric aerosol
hygroscopicity
secondary organic aerosol

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10.1002/2017GL073056

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Rastak, N., Pajunoja, A., Acosta Navarro, J. C., Ma, J., Song, M., Partridge, D. G., Kirkevåg, A., Leong, Y., Hu, W. W., Taylor, N. F., Lambe, A., Cerully, K., Bougiatioti, A., Liu, P., Krejci, R., Petäjä, T., Percival, C., Davidovits, P., Worsnop, D. R., ... Riipinen, I. (2017). Microphysical explanation of the RH-dependent water affinity of biogenic organic aerosol and its importance for climate. Geophysical Research Letters, 44(10), 5167-5177. https://doi.org/10.1002/2017GL073056

@article{4415b15ab9ef461090adf6da3042e25a,

title = "Microphysical explanation of the RH-dependent water affinity of biogenic organic aerosol and its importance for climate",

abstract = "A large fraction of atmospheric organic aerosol (OA) originates from natural emissions that are oxidized in the atmosphere to form secondary organic aerosol (SOA). Isoprene (IP) and monoterpenes (MT) are the most important precursors of SOA originating from forests. The climate impacts from OA are currently estimated through parameterizations of water uptake that drastically simplify the complexity of OA. We combine laboratory experiments, thermodynamic modeling, field observations, and climate modeling to (1) explain the molecular mechanisms behind RH-dependent SOA water-uptake with solubility and phase separation; (2) show that laboratory data on IP- and MT-SOA hygroscopicity are representative of ambient data with corresponding OA source profiles; and (3) demonstrate the sensitivity of the modeled aerosol climate effect to assumed OA water affinity. We conclude that the commonly used single-parameter hygroscopicity framework can introduce significant error when quantifying the climate effects of organic aerosol. The results highlight the need for better constraints on the overall global OA mass loadings and its molecular composition, including currently underexplored anthropogenic and marine OA sources.",

keywords = "aerosol-climate interactions, aerosol-water interactions, atmospheric aerosol, hygroscopicity, secondary organic aerosol",

author = "N. Rastak and A. Pajunoja and \{Acosta Navarro\}, \{J. C.\} and J. Ma and M. Song and Partridge, \{D. G.\} and A. Kirkev{\aa}g and Y. Leong and Hu, \{W. W.\} and Taylor, \{N. F.\} and A. Lambe and K. Cerully and A. Bougiatioti and P. Liu and R. Krejci and T. Pet{\"a}j{\"a} and C. Percival and P. Davidovits and Worsnop, \{D. R.\} and Ekman, \{A. M.L.\} and A. Nenes and S. Martin and Jimenez, \{J. L.\} and Collins, \{D. R.\} and Topping, \{D. O.\} and Bertram, \{A. K.\} and A. Zuend and A. Virtanen and I. Riipinen",

note = "Publisher Copyright: {\textcopyright}2017. The Authors.",

year = "2017",

month = may,

day = "28",

doi = "10.1002/2017GL073056",

language = "English",

volume = "44",

pages = "5167--5177",

journal = "Geophysical Research Letters",

issn = "0094-8276",

number = "10",

}

Rastak, N, Pajunoja, A, Acosta Navarro, JC, Ma, J, Song, M, Partridge, DG, Kirkevåg, A, Leong, Y, Hu, WW, Taylor, NF, Lambe, A, Cerully, K, Bougiatioti, A, Liu, P, Krejci, R, Petäjä, T, Percival, C, Davidovits, P, Worsnop, DR, Ekman, AML, Nenes, A, Martin, S, Jimenez, JL, Collins, DR, Topping, DO, Bertram, AK, Zuend, A, Virtanen, A & Riipinen, I 2017, 'Microphysical explanation of the RH-dependent water affinity of biogenic organic aerosol and its importance for climate', Geophysical Research Letters, vol. 44, no. 10, pp. 5167-5177. https://doi.org/10.1002/2017GL073056

TY - JOUR

T1 - Microphysical explanation of the RH-dependent water affinity of biogenic organic aerosol and its importance for climate

AU - Rastak, N.

AU - Pajunoja, A.

AU - Acosta Navarro, J. C.

AU - Ma, J.

AU - Song, M.

AU - Partridge, D. G.

AU - Kirkevåg, A.

AU - Leong, Y.

AU - Hu, W. W.

AU - Taylor, N. F.

AU - Lambe, A.

AU - Cerully, K.

AU - Bougiatioti, A.

AU - Liu, P.

AU - Krejci, R.

AU - Petäjä, T.

AU - Percival, C.

AU - Davidovits, P.

AU - Worsnop, D. R.

AU - Ekman, A. M.L.

AU - Nenes, A.

AU - Martin, S.

AU - Jimenez, J. L.

AU - Collins, D. R.

AU - Topping, D. O.

AU - Bertram, A. K.

AU - Zuend, A.

AU - Virtanen, A.

AU - Riipinen, I.

PY - 2017/5/28

Y1 - 2017/5/28

N2 - A large fraction of atmospheric organic aerosol (OA) originates from natural emissions that are oxidized in the atmosphere to form secondary organic aerosol (SOA). Isoprene (IP) and monoterpenes (MT) are the most important precursors of SOA originating from forests. The climate impacts from OA are currently estimated through parameterizations of water uptake that drastically simplify the complexity of OA. We combine laboratory experiments, thermodynamic modeling, field observations, and climate modeling to (1) explain the molecular mechanisms behind RH-dependent SOA water-uptake with solubility and phase separation; (2) show that laboratory data on IP- and MT-SOA hygroscopicity are representative of ambient data with corresponding OA source profiles; and (3) demonstrate the sensitivity of the modeled aerosol climate effect to assumed OA water affinity. We conclude that the commonly used single-parameter hygroscopicity framework can introduce significant error when quantifying the climate effects of organic aerosol. The results highlight the need for better constraints on the overall global OA mass loadings and its molecular composition, including currently underexplored anthropogenic and marine OA sources.

AB - A large fraction of atmospheric organic aerosol (OA) originates from natural emissions that are oxidized in the atmosphere to form secondary organic aerosol (SOA). Isoprene (IP) and monoterpenes (MT) are the most important precursors of SOA originating from forests. The climate impacts from OA are currently estimated through parameterizations of water uptake that drastically simplify the complexity of OA. We combine laboratory experiments, thermodynamic modeling, field observations, and climate modeling to (1) explain the molecular mechanisms behind RH-dependent SOA water-uptake with solubility and phase separation; (2) show that laboratory data on IP- and MT-SOA hygroscopicity are representative of ambient data with corresponding OA source profiles; and (3) demonstrate the sensitivity of the modeled aerosol climate effect to assumed OA water affinity. We conclude that the commonly used single-parameter hygroscopicity framework can introduce significant error when quantifying the climate effects of organic aerosol. The results highlight the need for better constraints on the overall global OA mass loadings and its molecular composition, including currently underexplored anthropogenic and marine OA sources.

KW - aerosol-climate interactions

KW - aerosol-water interactions

KW - atmospheric aerosol

KW - hygroscopicity

KW - secondary organic aerosol

UR - https://www.scopus.com/pages/publications/85019918429

U2 - 10.1002/2017GL073056

DO - 10.1002/2017GL073056

M3 - Journal article

AN - SCOPUS:85019918429

SN - 0094-8276

VL - 44

SP - 5167

EP - 5177

JO - Geophysical Research Letters

JF - Geophysical Research Letters

IS - 10

ER -

Microphysical explanation of the RH-dependent water affinity of biogenic organic aerosol and its importance for climate

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