Wintertime Abundance and Sources of Key Trace Gas and Particle Species in Fairbanks, Alaska

Damien T. Ketcherside; Robert J. Yokelson; Vanessa Selimovic; Ellis S. Robinson; Meeta Cesler-Maloney; Andrew L. Holen; Judy Wu; Brice Temime-Roussel; Amna Ijaz; Jonas Kuhn; Allison Moon; Gianluca Pappaccogli; Karolina Cysneiros de Carvalho; Stefano Decesari; Becky Alexander; Brent J. Williams; Barbara D’Anna; Jochen Stutz; Kerri A. Pratt; Peter F. DeCarlo; Jingqui Mao; William R. Simpson; Philip K. Hopke; Lu Hu

doi:10.1029/2025JD043677

Wintertime Abundance and Sources of Key Trace Gas and Particle Species in Fairbanks, Alaska

Damien T. Ketcherside, Robert J. Yokelson, Vanessa Selimovic, Ellis S. Robinson, Meeta Cesler-Maloney, Andrew L. Holen, Judy Wu, Brice Temime-Roussel, Amna Ijaz, Jonas Kuhn, Allison Moon, Gianluca Pappaccogli, Karolina Cysneiros de Carvalho, Stefano Decesari, Becky Alexander, Brent J. Williams, Barbara D’Anna, Jochen Stutz, Kerri A. Pratt, Peter F. DeCarloJingqui Mao, William R. Simpson, Philip K. Hopke, Lu Hu

Chemistry and Biochemistry

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

Abstract

We investigated how various sources contributed to observations of over 40 trace gas and particulate species in a typical Fairbanks residential neighborhood during the Alaskan Layered Pollution and Chemical Analysis campaign in January–February 2022. Aromatic volatile organic compounds (VOCs) accounted for ∼50% of measured VOCs (molar ratio), while methanol and ethanol accounted for ∼34%. The total wintertime VOC burden and contribution from aromatics were much higher than other US urban areas. Based on diel cycles and positive matrix factorization (PMF) analyses, we find traffic was the largest source of NO, CO, black carbon, and aromatic VOCs. Formic and acetic acid, hydroxyacetone, furanoids, and other VOCs were primarily attributed to residential wood combustion (RWC). Formaldehyde was one of several VOCs featuring significant contributions from multiple sources: RWC (∼35%), aging (∼30%), traffic (∼21%), and heating oil combustion (HO, ∼14%). PMF solutions assigned primary fine particulate matter to RWC (10%–30%), traffic (25%–40%), and HO (30%–60%), the latter likely reflecting high sulfur emissions from older furnaces and fast secondary chemistry. Despite cold and dark conditions, secondary processes impacted many trace gas and particle species' budget by ±10%–20% and more in some cases. Transport of O₃-rich regional air into Fairbanks contributed to aging, specifically NO₃ radical formation. This work highlights a long-term trend observed in Fairbanks: increasing traffic and decreasing RWC relative contributions as total pollution decreases. Fairbanks exports a relatively fresh pollutant mixture to the regional arctic, the fate of which warrants future study.

Original language	English
Article number	e2025JD043677
Journal	Journal of Geophysical Research: Atmospheres
Volume	130
Issue number	15
DOIs	https://doi.org/10.1029/2025JD043677
State	Published - Aug 16 2025

Keywords

particulate matter
positive matrix factorization
residential heating
source apportionment
urban arctic emissions
volatile organic compounds

UN SDGs

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

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10.1029/2025JD043677

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Ketcherside, D. T., Yokelson, R. J., Selimovic, V., Robinson, E. S., Cesler-Maloney, M., Holen, A. L., Wu, J., Temime-Roussel, B., Ijaz, A., Kuhn, J., Moon, A., Pappaccogli, G., Cysneiros de Carvalho, K., Decesari, S., Alexander, B., Williams, B. J., D’Anna, B., Stutz, J., Pratt, K. A., ... Hu, L. (2025). Wintertime Abundance and Sources of Key Trace Gas and Particle Species in Fairbanks, Alaska. Journal of Geophysical Research: Atmospheres, 130(15), Article e2025JD043677. https://doi.org/10.1029/2025JD043677

@article{2bbbf12171c6432abd64c6179f671029,

title = "Wintertime Abundance and Sources of Key Trace Gas and Particle Species in Fairbanks, Alaska",

abstract = "We investigated how various sources contributed to observations of over 40 trace gas and particulate species in a typical Fairbanks residential neighborhood during the Alaskan Layered Pollution and Chemical Analysis campaign in January–February 2022. Aromatic volatile organic compounds (VOCs) accounted for ∼50\% of measured VOCs (molar ratio), while methanol and ethanol accounted for ∼34\%. The total wintertime VOC burden and contribution from aromatics were much higher than other US urban areas. Based on diel cycles and positive matrix factorization (PMF) analyses, we find traffic was the largest source of NO, CO, black carbon, and aromatic VOCs. Formic and acetic acid, hydroxyacetone, furanoids, and other VOCs were primarily attributed to residential wood combustion (RWC). Formaldehyde was one of several VOCs featuring significant contributions from multiple sources: RWC (∼35\%), aging (∼30\%), traffic (∼21\%), and heating oil combustion (HO, ∼14\%). PMF solutions assigned primary fine particulate matter to RWC (10\%–30\%), traffic (25\%–40\%), and HO (30\%–60\%), the latter likely reflecting high sulfur emissions from older furnaces and fast secondary chemistry. Despite cold and dark conditions, secondary processes impacted many trace gas and particle species' budget by ±10\%–20\% and more in some cases. Transport of O3-rich regional air into Fairbanks contributed to aging, specifically NO3 radical formation. This work highlights a long-term trend observed in Fairbanks: increasing traffic and decreasing RWC relative contributions as total pollution decreases. Fairbanks exports a relatively fresh pollutant mixture to the regional arctic, the fate of which warrants future study.",

keywords = "particulate matter, positive matrix factorization, residential heating, source apportionment, urban arctic emissions, volatile organic compounds",

author = "Ketcherside, \{Damien T.\} and Yokelson, \{Robert J.\} and Vanessa Selimovic and Robinson, \{Ellis S.\} and Meeta Cesler-Maloney and Holen, \{Andrew L.\} and Judy Wu and Brice Temime-Roussel and Amna Ijaz and Jonas Kuhn and Allison Moon and Gianluca Pappaccogli and \{Cysneiros de Carvalho\}, Karolina and Stefano Decesari and Becky Alexander and Williams, \{Brent J.\} and Barbara D{\textquoteright}Anna and Jochen Stutz and Pratt, \{Kerri A.\} and DeCarlo, \{Peter F.\} and Jingqui Mao and Simpson, \{William R.\} and Hopke, \{Philip K.\} and Lu Hu",

year = "2025",

month = aug,

day = "16",

doi = "10.1029/2025JD043677",

language = "English",

volume = "130",

journal = "Journal of Geophysical Research: Atmospheres",

issn = "2169-897X",

publisher = "Wiley-Blackwell Publishing Ltd",

number = "15",

}

Ketcherside, DT, Yokelson, RJ, Selimovic, V, Robinson, ES, Cesler-Maloney, M, Holen, AL, Wu, J, Temime-Roussel, B, Ijaz, A, Kuhn, J, Moon, A, Pappaccogli, G, Cysneiros de Carvalho, K, Decesari, S, Alexander, B, Williams, BJ, D’Anna, B, Stutz, J, Pratt, KA, DeCarlo, PF, Mao, J, Simpson, WR, Hopke, PK & Hu, L 2025, 'Wintertime Abundance and Sources of Key Trace Gas and Particle Species in Fairbanks, Alaska', Journal of Geophysical Research: Atmospheres, vol. 130, no. 15, e2025JD043677. https://doi.org/10.1029/2025JD043677

TY - JOUR

T1 - Wintertime Abundance and Sources of Key Trace Gas and Particle Species in Fairbanks, Alaska

AU - Ketcherside, Damien T.

AU - Yokelson, Robert J.

AU - Selimovic, Vanessa

AU - Robinson, Ellis S.

AU - Cesler-Maloney, Meeta

AU - Holen, Andrew L.

AU - Wu, Judy

AU - Temime-Roussel, Brice

AU - Ijaz, Amna

AU - Kuhn, Jonas

AU - Moon, Allison

AU - Pappaccogli, Gianluca

AU - Cysneiros de Carvalho, Karolina

AU - Decesari, Stefano

AU - Alexander, Becky

AU - Williams, Brent J.

AU - D’Anna, Barbara

AU - Stutz, Jochen

AU - Pratt, Kerri A.

AU - DeCarlo, Peter F.

AU - Mao, Jingqui

AU - Simpson, William R.

AU - Hopke, Philip K.

AU - Hu, Lu

PY - 2025/8/16

Y1 - 2025/8/16

N2 - We investigated how various sources contributed to observations of over 40 trace gas and particulate species in a typical Fairbanks residential neighborhood during the Alaskan Layered Pollution and Chemical Analysis campaign in January–February 2022. Aromatic volatile organic compounds (VOCs) accounted for ∼50% of measured VOCs (molar ratio), while methanol and ethanol accounted for ∼34%. The total wintertime VOC burden and contribution from aromatics were much higher than other US urban areas. Based on diel cycles and positive matrix factorization (PMF) analyses, we find traffic was the largest source of NO, CO, black carbon, and aromatic VOCs. Formic and acetic acid, hydroxyacetone, furanoids, and other VOCs were primarily attributed to residential wood combustion (RWC). Formaldehyde was one of several VOCs featuring significant contributions from multiple sources: RWC (∼35%), aging (∼30%), traffic (∼21%), and heating oil combustion (HO, ∼14%). PMF solutions assigned primary fine particulate matter to RWC (10%–30%), traffic (25%–40%), and HO (30%–60%), the latter likely reflecting high sulfur emissions from older furnaces and fast secondary chemistry. Despite cold and dark conditions, secondary processes impacted many trace gas and particle species' budget by ±10%–20% and more in some cases. Transport of O3-rich regional air into Fairbanks contributed to aging, specifically NO3 radical formation. This work highlights a long-term trend observed in Fairbanks: increasing traffic and decreasing RWC relative contributions as total pollution decreases. Fairbanks exports a relatively fresh pollutant mixture to the regional arctic, the fate of which warrants future study.

AB - We investigated how various sources contributed to observations of over 40 trace gas and particulate species in a typical Fairbanks residential neighborhood during the Alaskan Layered Pollution and Chemical Analysis campaign in January–February 2022. Aromatic volatile organic compounds (VOCs) accounted for ∼50% of measured VOCs (molar ratio), while methanol and ethanol accounted for ∼34%. The total wintertime VOC burden and contribution from aromatics were much higher than other US urban areas. Based on diel cycles and positive matrix factorization (PMF) analyses, we find traffic was the largest source of NO, CO, black carbon, and aromatic VOCs. Formic and acetic acid, hydroxyacetone, furanoids, and other VOCs were primarily attributed to residential wood combustion (RWC). Formaldehyde was one of several VOCs featuring significant contributions from multiple sources: RWC (∼35%), aging (∼30%), traffic (∼21%), and heating oil combustion (HO, ∼14%). PMF solutions assigned primary fine particulate matter to RWC (10%–30%), traffic (25%–40%), and HO (30%–60%), the latter likely reflecting high sulfur emissions from older furnaces and fast secondary chemistry. Despite cold and dark conditions, secondary processes impacted many trace gas and particle species' budget by ±10%–20% and more in some cases. Transport of O3-rich regional air into Fairbanks contributed to aging, specifically NO3 radical formation. This work highlights a long-term trend observed in Fairbanks: increasing traffic and decreasing RWC relative contributions as total pollution decreases. Fairbanks exports a relatively fresh pollutant mixture to the regional arctic, the fate of which warrants future study.

KW - particulate matter

KW - positive matrix factorization

KW - residential heating

KW - source apportionment

KW - urban arctic emissions

KW - volatile organic compounds

UR - https://www.scopus.com/pages/publications/105012585338

U2 - 10.1029/2025JD043677

DO - 10.1029/2025JD043677

M3 - Article

AN - SCOPUS:105012585338

SN - 2169-897X

VL - 130

JO - Journal of Geophysical Research: Atmospheres

JF - Journal of Geophysical Research: Atmospheres

IS - 15

M1 - e2025JD043677

ER -

Wintertime Abundance and Sources of Key Trace Gas and Particle Species in Fairbanks, Alaska

Abstract

Keywords

UN SDGs

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