Boosting aerosol surface effects : strongly enhanced cooperative surface propensity of atmospherically relevant organic molecular ions in aqueous solution

Kaur, Harmanjot; Thürmer, Stephan; Gholami, Shirin; Credidio, Bruno; Trinter, Florian; Vasconcelos, Debora; Marinho, Ricardo; Pinheiro, Joel; Bluhm, Hendrik; Naves De Brito, Arnaldo; Öhrwall, Gunnar; Winter, Bernd; Björneholm, Olle

Boosting aerosol surface effects : strongly enhanced cooperative surface propensity of atmospherically relevant organic molecular ions in aqueous solution

Mark

Kaur, Harmanjot ; Thürmer, Stephan ; Gholami, Shirin ; Credidio, Bruno ; Trinter, Florian ; Vasconcelos, Debora ; Marinho, Ricardo ^LU ; Pinheiro, Joel ; Bluhm, Hendrik and Naves De Brito, Arnaldo , et al. (2025) In Atmospheric Chemistry and Physics 25(6). p.3503-3518

Abstract: The effects of atmospheric aerosols are key uncertainties in climate models. One reason is the complex aerosol composition which includes a relatively large fraction of organics. Another reason is the small size of aerosols, which makes surface effects and processes important. These two factors make surface-active organics relevant for atmospheric aerosols, as they can affect crucial processes, such as chemical aging and water accommodation, as well as properties such as the surface tension, which drives droplet formation. Two exemplary types of atmospherically relevant organics are carboxylic acids and alkyl amines, and often both are found together within aerosols. In the most atmospherically significant pH range, these exist as... (More); The effects of atmospheric aerosols are key uncertainties in climate models. One reason is the complex aerosol composition which includes a relatively large fraction of organics. Another reason is the small size of aerosols, which makes surface effects and processes important. These two factors make surface-active organics relevant for atmospheric aerosols, as they can affect crucial processes, such as chemical aging and water accommodation, as well as properties such as the surface tension, which drives droplet formation. Two exemplary types of atmospherically relevant organics are carboxylic acids and alkyl amines, and often both are found together within aerosols. In the most atmospherically significant pH range, these exist as alkyl-carboxylate ions and alkyl-ammonium ions. Using liquid-jet photoelectron spectroscopy, tuned to high surface sensitivity, we measured the alkyl-carboxylate anions and the alkyl-ammonium cations of alkyl chain lengths of 1 to 6 carbon atoms, both as single-component and mixed-component aqueous solutions. This enabled us to systematically study how their surface propensity is affected by the length of the alkyl chains and how cooperative ion-ion interactions result in strongly increased surface propensity. An exponential increase in surface propensity is found for the single-species solutions, with cooperative solute-solute effects in mixed solutions of 1 : 1 molar ratio drastically increasing the number of molecules present at the solutions' surfaces up to a factor of several hundred. This cooperative surface propensity is shown to strongly affect the amounts of organics at the surface. These changes can significantly influence radiative forcing via aerosol growth, cloud condensation nuclei activity, and aerosol chemical aging. Our results demonstrate the principal feasibility of a more advanced input of molecular details for creating parameterized descriptions of aerosol surface composition needed to properly account for their impacts in climate models.
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Please use this url to cite or link to this publication: https://lup.lub.lu.se/record/30ebefa5-a9c8-4e1a-9ffa-015cb7c9576a

author

Kaur, Harmanjot ; Thürmer, Stephan ; Gholami, Shirin ; Credidio, Bruno ; Trinter, Florian ; Vasconcelos, Debora ; Marinho, Ricardo ^LU ; Pinheiro, Joel ; Bluhm, Hendrik and Naves De Brito, Arnaldo , et al. (More)

Kaur, Harmanjot ; Thürmer, Stephan ; Gholami, Shirin ; Credidio, Bruno ; Trinter, Florian ; Vasconcelos, Debora ; Marinho, Ricardo ^LU ; Pinheiro, Joel ; Bluhm, Hendrik ; Naves De Brito, Arnaldo ; Öhrwall, Gunnar ^LU

; Winter, Bernd and Björneholm, Olle ^LU (Less)

organization

MAX IV, Science division

publishing date

2025-03-25

type

Contribution to journal

publication status

published

subject

in

Atmospheric Chemistry and Physics

volume

25

issue

6

pages

16 pages

publisher

Copernicus GmbH

external identifiers

scopus:105000937995

ISSN

1680-7316

DOI

10.5194/acp-25-3503-2025

language

English

LU publication?

yes

additional info

id

30ebefa5-a9c8-4e1a-9ffa-015cb7c9576a

date added to LUP

2025-12-05 11:53:27

date last changed

2025-12-05 11:54:38

@article{30ebefa5-a9c8-4e1a-9ffa-015cb7c9576a,
  abstract     = {{<p>The effects of atmospheric aerosols are key uncertainties in climate models. One reason is the complex aerosol composition which includes a relatively large fraction of organics. Another reason is the small size of aerosols, which makes surface effects and processes important. These two factors make surface-active organics relevant for atmospheric aerosols, as they can affect crucial processes, such as chemical aging and water accommodation, as well as properties such as the surface tension, which drives droplet formation. Two exemplary types of atmospherically relevant organics are carboxylic acids and alkyl amines, and often both are found together within aerosols. In the most atmospherically significant pH range, these exist as alkyl-carboxylate ions and alkyl-ammonium ions. Using liquid-jet photoelectron spectroscopy, tuned to high surface sensitivity, we measured the alkyl-carboxylate anions and the alkyl-ammonium cations of alkyl chain lengths of 1 to 6 carbon atoms, both as single-component and mixed-component aqueous solutions. This enabled us to systematically study how their surface propensity is affected by the length of the alkyl chains and how cooperative ion-ion interactions result in strongly increased surface propensity. An exponential increase in surface propensity is found for the single-species solutions, with cooperative solute-solute effects in mixed solutions of 1 : 1 molar ratio drastically increasing the number of molecules present at the solutions' surfaces up to a factor of several hundred. This cooperative surface propensity is shown to strongly affect the amounts of organics at the surface. These changes can significantly influence radiative forcing via aerosol growth, cloud condensation nuclei activity, and aerosol chemical aging. Our results demonstrate the principal feasibility of a more advanced input of molecular details for creating parameterized descriptions of aerosol surface composition needed to properly account for their impacts in climate models.</p>}},
  author       = {{Kaur, Harmanjot and Thürmer, Stephan and Gholami, Shirin and Credidio, Bruno and Trinter, Florian and Vasconcelos, Debora and Marinho, Ricardo and Pinheiro, Joel and Bluhm, Hendrik and Naves De Brito, Arnaldo and Öhrwall, Gunnar and Winter, Bernd and Björneholm, Olle}},
  issn         = {{1680-7316}},
  language     = {{eng}},
  month        = {{03}},
  number       = {{6}},
  pages        = {{3503--3518}},
  publisher    = {{Copernicus GmbH}},
  series       = {{Atmospheric Chemistry and Physics}},
  title        = {{Boosting aerosol surface effects : strongly enhanced cooperative surface propensity of atmospherically relevant organic molecular ions in aqueous solution}},
  url          = {{http://dx.doi.org/10.5194/acp-25-3503-2025}},
  doi          = {{10.5194/acp-25-3503-2025}},
  volume       = {{25}},
  year         = {{2025}},
}

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Boosting aerosol surface effects : strongly enhanced cooperative surface propensity of atmospherically relevant organic molecular ions in aqueous solution