Isoprene Aerosol Growth in the Upper Troposphere: Application of the Diagonal Volatility Basis Set to CLOUD Chamber Measurements

CLOUD_CERN; Eva Sommer; Aleksandra Morawiec

doi:10.1021/acsestair.5c00106

Isoprene Aerosol Growth in the Upper Troposphere: Application of the Diagonal Volatility Basis Set to CLOUD Chamber Measurements

CLOUD_CERN
, Eva Sommer
, Aleksandra Morawiec

Aerosolphysik und Umweltphysik

Veröffentlichungen: Beitrag in Fachzeitschrift › Artikel › Peer Reviewed

Abstract

Isoprene oxygenated organic molecules (IP-OOM) can nucleate new particles in the upper troposphere. These particles may grow into cloud condensation nuclei and influence the clouds and climate. However, little is known about the individual species driving growth and whether they undergo condensed-phase reactions. We conducted isoprene oxidation experiments at 223 and 243 K in the CLOUD chamber at CERN. Gas-phase concentrations were measured with chemical ionization mass spectrometers (NO3–-CIMS, Br–-MION2-CIMS, and NH4+-CIMS). Growth rates from 8 to 20 nm were measured by a Neutral Cluster and Air Ion Spectrometer. Particle-phase composition was measured by a filter sampling chemical ionization mass spectrometer. We use the diagonal volatility basis set (dVBS) analysis framework to compare gas- and particle-phase measurements and assess species and processes influencing growth. We find that kinetically limited condensation of a few species dominates particle composition and growth. Particle-phase processes, including oligomerization and organonitrate hydrolysis, do not influence the early growth. dVBS growth rate predictions can explain 90% of the measured growth, dominated by kinetic condensation of low-volatility species. Our findings indicate that initial growth of IP-OOM particles under cold, low-acid conditions may be controlled and modeled by the kinetically limited condensation of low-volatility compounds.

Originalsprache	Englisch
Seiten (von - bis)	2092-2104
Seitenumfang	13
Fachzeitschrift	ACS ES&T Air
Jahrgang	2
Ausgabenummer	10
DOIs	https://doi.org/10.1021/acsestair.5c00106
Publikationsstatus	Veröffentlicht - 10 Okt. 2025

Fördermittel

The authors thank CERN for supporting CLOUD with important technical and financial resources and for providing a particle beam from the CERN Proton Synchrotron. The authors appreciate the support for this work from the National Science Foundation (grants no. 2132089, 2215489, 2215522, & 2336463). This research has also been funded by the Vienna Science and Technology Fund (project no. VRG22-003), the Austrian Science Fund (10.55776/PAT8221324), the European Union’s Horizon Europe programme (Marie Sklodowska Curie action no. 101073026), the European Union’s Horizon 2020 research and innovation programme (no. 856612), the German Federal Ministry of Education and Research (project no. 01LK2201A), the Swiss National Science Foundation (no. 200021_213071), and the Research Council of Finland (nos. 346371, 357905, 359331, 359343, & 364229). The authors also appreciate the support provided by administrative and other staff at Carnegie Mellon University and CERN, without whom this work would not be possible.

Träger	Trägernummer
Fonds zur Förderung der wissenschaftlichen Forschung (FWF)	10.55776/PAT8221324
European Commission	101073026

UN SDGs

Dieser Output leistet einen Beitrag zu folgendem(n) Ziel(en) für nachhaltige Entwicklung

SDG 13 – Maßnahmen zum Klimaschutz

ÖFOS 2012

105208 Atmosphärenchemie
103039 Aerosolphysik
103037 Umweltphysik

Zugriff auf Dokument

10.1021/acsestair.5c00106Lizenz: CC BY 4.0

Andere Dateien und Links

Verknüpfung zur Publikation in Scopus

Matrix Isolation von atmosphärischen Nukleationsclustern
Winkler, P. (Projektleiter*in)
1/11/24 → 31/10/27
Projekt: Forschungsförderung
CLOUD-DOC: CLOUD Doctoral Network
Winkler, P. (Projektleiter*in)
1/09/22 → 31/08/26
Projekt: Forschungsförderung

Zitationsweisen

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title = "Isoprene Aerosol Growth in the Upper Troposphere: Application of the Diagonal Volatility Basis Set to CLOUD Chamber Measurements",

abstract = "Isoprene oxygenated organic molecules (IP-OOM) can nucleate new particles in the upper troposphere. These particles may grow into cloud condensation nuclei and influence the clouds and climate. However, little is known about the individual species driving growth and whether they undergo condensed-phase reactions. We conducted isoprene oxidation experiments at 223 and 243 K in the CLOUD chamber at CERN. Gas-phase concentrations were measured with chemical ionization mass spectrometers (NO3–-CIMS, Br–-MION2-CIMS, and NH4+-CIMS). Growth rates from 8 to 20 nm were measured by a Neutral Cluster and Air Ion Spectrometer. Particle-phase composition was measured by a filter sampling chemical ionization mass spectrometer. We use the diagonal volatility basis set (dVBS) analysis framework to compare gas- and particle-phase measurements and assess species and processes influencing growth. We find that kinetically limited condensation of a few species dominates particle composition and growth. Particle-phase processes, including oligomerization and organonitrate hydrolysis, do not influence the early growth. dVBS growth rate predictions can explain 90\% of the measured growth, dominated by kinetic condensation of low-volatility species. Our findings indicate that initial growth of IP-OOM particles under cold, low-acid conditions may be controlled and modeled by the kinetically limited condensation of low-volatility compounds.",

keywords = "atmospheric chemistry, chamber measurements, isoprene, particle growth, volatility",

author = "CLOUD\_CERN and Nirvan Bhattacharyya and Brandon Lopez and Jenna DeVivo and Russell, \{Douglas M.\} and Jiali Shen and Eva Sommer and Jo{\~a}o Almeida and Antonio Amorim and Beckmann, \{Hannah M.\} and Mattia Busato and Canagaratna, \{Manjula R.\} and Lucia Caudillo and Anouck Chassaing and Theodoros Christoudias and Lubna Dada and Imad El-Haddad and Flagan, \{Richard C.\} and Hartwig Harder and Bernhard Judmaier and \{Kaniyodical Sebastian\}, Milin and Jasper Kirkby and Hannah Klebach and Markku Kulmala and Felix Kunkler and Katrianne Lehtipalo and Lu Liu and Bernhard Mentler and Ottmar M{\"o}hler and Aleksandra Morawiec and Tuukka Pet{\"a}j{\"a} and Pedro Rato and Birte R{\"o}rup and Samuel Ruhl and Wiebke Scholz and Mario Simon and Ant{\'o}nio T{\'o}me and Yandong Tong and Jens Top and Umo, \{Nsikanabasi Silas\} and Rainer Volkamer and Jakob Weissbacher and Worsnop, \{Doug R.\} and Christos Xenofontos and Boxing Yang and Wenjuan Yu and Marcel Zauner-Wieczorek and Imad Zgheib and Jiangyi Zhang and Zhensen Zheng and He, \{Xu Cheng\}",

note = "Published as part of ACS ES\&T Air special issue “John H. Seinfeld Festschrift”.",

year = "2025",

month = oct,

day = "10",

doi = "10.1021/acsestair.5c00106",

language = "English",

volume = "2",

pages = "2092--2104",

journal = "ACS ES\&T Air",

issn = "2837-1402",

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number = "10",

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TY - JOUR

T1 - Isoprene Aerosol Growth in the Upper Troposphere: Application of the Diagonal Volatility Basis Set to CLOUD Chamber Measurements

AU - CLOUD_CERN

AU - Bhattacharyya, Nirvan

AU - Lopez, Brandon

AU - DeVivo, Jenna

AU - Russell, Douglas M.

AU - Shen, Jiali

AU - Sommer, Eva

AU - Almeida, João

AU - Amorim, Antonio

AU - Beckmann, Hannah M.

AU - Busato, Mattia

AU - Canagaratna, Manjula R.

AU - Caudillo, Lucia

AU - Chassaing, Anouck

AU - Christoudias, Theodoros

AU - Dada, Lubna

AU - El-Haddad, Imad

AU - Flagan, Richard C.

AU - Harder, Hartwig

AU - Judmaier, Bernhard

AU - Kaniyodical Sebastian, Milin

AU - Kirkby, Jasper

AU - Klebach, Hannah

AU - Kulmala, Markku

AU - Kunkler, Felix

AU - Lehtipalo, Katrianne

AU - Liu, Lu

AU - Mentler, Bernhard

AU - Möhler, Ottmar

AU - Morawiec, Aleksandra

AU - Petäjä, Tuukka

AU - Rato, Pedro

AU - Rörup, Birte

AU - Ruhl, Samuel

AU - Scholz, Wiebke

AU - Simon, Mario

AU - Tóme, António

AU - Tong, Yandong

AU - Top, Jens

AU - Umo, Nsikanabasi Silas

AU - Volkamer, Rainer

AU - Weissbacher, Jakob

AU - Worsnop, Doug R.

AU - Xenofontos, Christos

AU - Yang, Boxing

AU - Yu, Wenjuan

AU - Zauner-Wieczorek, Marcel

AU - Zgheib, Imad

AU - Zhang, Jiangyi

AU - Zheng, Zhensen

AU - He, Xu Cheng

N1 - Published as part of ACS ES&T Air special issue “John H. Seinfeld Festschrift”.

PY - 2025/10/10

Y1 - 2025/10/10

N2 - Isoprene oxygenated organic molecules (IP-OOM) can nucleate new particles in the upper troposphere. These particles may grow into cloud condensation nuclei and influence the clouds and climate. However, little is known about the individual species driving growth and whether they undergo condensed-phase reactions. We conducted isoprene oxidation experiments at 223 and 243 K in the CLOUD chamber at CERN. Gas-phase concentrations were measured with chemical ionization mass spectrometers (NO3–-CIMS, Br–-MION2-CIMS, and NH4+-CIMS). Growth rates from 8 to 20 nm were measured by a Neutral Cluster and Air Ion Spectrometer. Particle-phase composition was measured by a filter sampling chemical ionization mass spectrometer. We use the diagonal volatility basis set (dVBS) analysis framework to compare gas- and particle-phase measurements and assess species and processes influencing growth. We find that kinetically limited condensation of a few species dominates particle composition and growth. Particle-phase processes, including oligomerization and organonitrate hydrolysis, do not influence the early growth. dVBS growth rate predictions can explain 90% of the measured growth, dominated by kinetic condensation of low-volatility species. Our findings indicate that initial growth of IP-OOM particles under cold, low-acid conditions may be controlled and modeled by the kinetically limited condensation of low-volatility compounds.

AB - Isoprene oxygenated organic molecules (IP-OOM) can nucleate new particles in the upper troposphere. These particles may grow into cloud condensation nuclei and influence the clouds and climate. However, little is known about the individual species driving growth and whether they undergo condensed-phase reactions. We conducted isoprene oxidation experiments at 223 and 243 K in the CLOUD chamber at CERN. Gas-phase concentrations were measured with chemical ionization mass spectrometers (NO3–-CIMS, Br–-MION2-CIMS, and NH4+-CIMS). Growth rates from 8 to 20 nm were measured by a Neutral Cluster and Air Ion Spectrometer. Particle-phase composition was measured by a filter sampling chemical ionization mass spectrometer. We use the diagonal volatility basis set (dVBS) analysis framework to compare gas- and particle-phase measurements and assess species and processes influencing growth. We find that kinetically limited condensation of a few species dominates particle composition and growth. Particle-phase processes, including oligomerization and organonitrate hydrolysis, do not influence the early growth. dVBS growth rate predictions can explain 90% of the measured growth, dominated by kinetic condensation of low-volatility species. Our findings indicate that initial growth of IP-OOM particles under cold, low-acid conditions may be controlled and modeled by the kinetically limited condensation of low-volatility compounds.

KW - atmospheric chemistry

KW - chamber measurements

KW - isoprene

KW - particle growth

KW - volatility

UR - https://www.scopus.com/pages/publications/105031159651

U2 - 10.1021/acsestair.5c00106

DO - 10.1021/acsestair.5c00106

M3 - Article

AN - SCOPUS:105031159651

SN - 2837-1402

VL - 2

SP - 2092

EP - 2104

JO - ACS ES&T Air

JF - ACS ES&T Air

IS - 10

ER -

Isoprene Aerosol Growth in the Upper Troposphere: Application of the Diagonal Volatility Basis Set to CLOUD Chamber Measurements

Abstract

Fördermittel

UN SDGs

ÖFOS 2012

Zugriff auf Dokument

Andere Dateien und Links

Fingerprint

Projekte

Matrix Isolation von atmosphärischen Nukleationsclustern

CLOUD-DOC: CLOUD Doctoral Network

Zitationsweisen