Organic carbon dry deposition outpaces atmospheric processing with unaccounted implications for air quality and freshwater ecosystems

John Liggio; Paul Makar; Shao Meng Li; Katherine Hayden; Andrea Darlington; Samar Moussa; Sumi Wren; Ralf Staebler; Jeremy Wentzell; Michael Wheeler; Amy Leithead; Richard Mittermeier; Julie Narayan; Mengistu Wolde; Dane Blanchard; Julian Aherne; Jane Kirk; Colin Lee; Craig Stroud; Junhua Zhang; Ayodeji Akingunola; Ali Katal; Philip Cheung; Roya Ghahreman; Mahtab Majdzadeh; Megan He; Jenna Ditto; Drew R. Gentner

doi:10.1126/sciadv.adr0259

Organic carbon dry deposition outpaces atmospheric processing with unaccounted implications for air quality and freshwater ecosystems

John Liggio, Paul Makar, Shao Meng Li, Katherine Hayden, Andrea Darlington, Samar Moussa, Sumi Wren, Ralf Staebler, Jeremy Wentzell, Michael Wheeler, Amy Leithead, Richard Mittermeier, Julie Narayan, Mengistu Wolde, Dane Blanchard, Julian Aherne, Jane Kirk, Colin Lee, Craig Stroud, Junhua ZhangAyodeji Akingunola, Ali Katal, Philip Cheung, Roya Ghahreman, Mahtab Majdzadeh, Megan He, Jenna Ditto, Drew R. Gentner

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Abstract

Dry deposition is an important yet poorly constrained process that removes reactive organic carbon from the atmosphere, making it unavailable for airborne chemical reactions and transferring it to other environmental systems. Using an aircraft-based measurement method, we provide large-scale estimates of total gas-phase organic carbon deposition rates and fluxes. Observed deposition rates downwind of large-scale unconventional oil operations reached up to 100 tC hour⁻¹, with fluxes exceeding 0.1 gC m⁻² hour⁻¹. The observed deposition lifetimes (τ_dep) were short enough (i.e., 4 ± 2 hours) to compete with chemical oxidation processes and affect the fate of atmospheric reactive carbon. Yet, much of this deposited organic carbon cannot be accounted for using traditional gas-phase deposition algorithms used in regional air quality models, signifying underrepresented, but influential, chemical-physical surface properties and processes. Furthermore, these fluxes represent a major unaccounted contribution of reactive carbon to downwind freshwater ecosystems that outweigh terrestrial sources, necessitating the inclusion of dry deposition in aquatic carbon balances and models.

Original language	English
Article number	eadr0259
Journal	Science Advances
Volume	11
Issue number	1
DOIs	https://doi.org/10.1126/sciadv.adr0259
State	Published - Jan 3 2025

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Liggio, J., Makar, P., Li, S. M., Hayden, K., Darlington, A., Moussa, S., Wren, S., Staebler, R., Wentzell, J., Wheeler, M., Leithead, A., Mittermeier, R., Narayan, J., Wolde, M., Blanchard, D., Aherne, J., Kirk, J., Lee, C., Stroud, C., ... Gentner, D. R. (2025). Organic carbon dry deposition outpaces atmospheric processing with unaccounted implications for air quality and freshwater ecosystems. Science Advances, 11(1), Article eadr0259. https://doi.org/10.1126/sciadv.adr0259

@article{94287a317df047b890e631a7f7396644,

title = "Organic carbon dry deposition outpaces atmospheric processing with unaccounted implications for air quality and freshwater ecosystems",

abstract = "Dry deposition is an important yet poorly constrained process that removes reactive organic carbon from the atmosphere, making it unavailable for airborne chemical reactions and transferring it to other environmental systems. Using an aircraft-based measurement method, we provide large-scale estimates of total gas-phase organic carbon deposition rates and fluxes. Observed deposition rates downwind of large-scale unconventional oil operations reached up to 100 tC hour−1, with fluxes exceeding 0.1 gC m−2 hour−1. The observed deposition lifetimes (τdep) were short enough (i.e., 4 ± 2 hours) to compete with chemical oxidation processes and affect the fate of atmospheric reactive carbon. Yet, much of this deposited organic carbon cannot be accounted for using traditional gas-phase deposition algorithms used in regional air quality models, signifying underrepresented, but influential, chemical-physical surface properties and processes. Furthermore, these fluxes represent a major unaccounted contribution of reactive carbon to downwind freshwater ecosystems that outweigh terrestrial sources, necessitating the inclusion of dry deposition in aquatic carbon balances and models.",

author = "John Liggio and Paul Makar and Li, {Shao Meng} and Katherine Hayden and Andrea Darlington and Samar Moussa and Sumi Wren and Ralf Staebler and Jeremy Wentzell and Michael Wheeler and Amy Leithead and Richard Mittermeier and Julie Narayan and Mengistu Wolde and Dane Blanchard and Julian Aherne and Jane Kirk and Colin Lee and Craig Stroud and Junhua Zhang and Ayodeji Akingunola and Ali Katal and Philip Cheung and Roya Ghahreman and Mahtab Majdzadeh and Megan He and Jenna Ditto and Gentner, {Drew R.}",

note = "Publisher Copyright: Copyright {\textcopyright} 2025 The Authors, some rights reserved.",

year = "2025",

month = jan,

day = "3",

doi = "10.1126/sciadv.adr0259",

language = "English",

volume = "11",

journal = "Science Advances",

issn = "2375-2548",

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Liggio, J, Makar, P, Li, SM, Hayden, K, Darlington, A, Moussa, S, Wren, S, Staebler, R, Wentzell, J, Wheeler, M, Leithead, A, Mittermeier, R, Narayan, J, Wolde, M, Blanchard, D, Aherne, J, Kirk, J, Lee, C, Stroud, C, Zhang, J, Akingunola, A, Katal, A, Cheung, P, Ghahreman, R, Majdzadeh, M, He, M, Ditto, J & Gentner, DR 2025, 'Organic carbon dry deposition outpaces atmospheric processing with unaccounted implications for air quality and freshwater ecosystems', Science Advances, vol. 11, no. 1, eadr0259. https://doi.org/10.1126/sciadv.adr0259

TY - JOUR

T1 - Organic carbon dry deposition outpaces atmospheric processing with unaccounted implications for air quality and freshwater ecosystems

AU - Liggio, John

AU - Makar, Paul

AU - Li, Shao Meng

AU - Hayden, Katherine

AU - Darlington, Andrea

AU - Moussa, Samar

AU - Wren, Sumi

AU - Staebler, Ralf

AU - Wentzell, Jeremy

AU - Wheeler, Michael

AU - Leithead, Amy

AU - Mittermeier, Richard

AU - Narayan, Julie

AU - Wolde, Mengistu

AU - Blanchard, Dane

AU - Aherne, Julian

AU - Kirk, Jane

AU - Lee, Colin

AU - Stroud, Craig

AU - Zhang, Junhua

AU - Akingunola, Ayodeji

AU - Katal, Ali

AU - Cheung, Philip

AU - Ghahreman, Roya

AU - Majdzadeh, Mahtab

AU - He, Megan

AU - Ditto, Jenna

AU - Gentner, Drew R.

PY - 2025/1/3

Y1 - 2025/1/3

N2 - Dry deposition is an important yet poorly constrained process that removes reactive organic carbon from the atmosphere, making it unavailable for airborne chemical reactions and transferring it to other environmental systems. Using an aircraft-based measurement method, we provide large-scale estimates of total gas-phase organic carbon deposition rates and fluxes. Observed deposition rates downwind of large-scale unconventional oil operations reached up to 100 tC hour−1, with fluxes exceeding 0.1 gC m−2 hour−1. The observed deposition lifetimes (τdep) were short enough (i.e., 4 ± 2 hours) to compete with chemical oxidation processes and affect the fate of atmospheric reactive carbon. Yet, much of this deposited organic carbon cannot be accounted for using traditional gas-phase deposition algorithms used in regional air quality models, signifying underrepresented, but influential, chemical-physical surface properties and processes. Furthermore, these fluxes represent a major unaccounted contribution of reactive carbon to downwind freshwater ecosystems that outweigh terrestrial sources, necessitating the inclusion of dry deposition in aquatic carbon balances and models.

AB - Dry deposition is an important yet poorly constrained process that removes reactive organic carbon from the atmosphere, making it unavailable for airborne chemical reactions and transferring it to other environmental systems. Using an aircraft-based measurement method, we provide large-scale estimates of total gas-phase organic carbon deposition rates and fluxes. Observed deposition rates downwind of large-scale unconventional oil operations reached up to 100 tC hour−1, with fluxes exceeding 0.1 gC m−2 hour−1. The observed deposition lifetimes (τdep) were short enough (i.e., 4 ± 2 hours) to compete with chemical oxidation processes and affect the fate of atmospheric reactive carbon. Yet, much of this deposited organic carbon cannot be accounted for using traditional gas-phase deposition algorithms used in regional air quality models, signifying underrepresented, but influential, chemical-physical surface properties and processes. Furthermore, these fluxes represent a major unaccounted contribution of reactive carbon to downwind freshwater ecosystems that outweigh terrestrial sources, necessitating the inclusion of dry deposition in aquatic carbon balances and models.

UR - http://www.scopus.com/inward/record.url?scp=85214589279&partnerID=8YFLogxK

U2 - 10.1126/sciadv.adr0259

DO - 10.1126/sciadv.adr0259

M3 - Article

C2 - 39752507

AN - SCOPUS:85214589279

SN - 2375-2548

VL - 11

JO - Science Advances

JF - Science Advances

IS - 1

M1 - eadr0259

ER -

Organic carbon dry deposition outpaces atmospheric processing with unaccounted implications for air quality and freshwater ecosystems

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