Complex Effects of Reduced Mobile Source Emissions on Submicron Particulate Matter Concentrations in Los Angeles

Benjamin C. Schulze; Christopher M. Kenseth; Ryan X. Ward; Elyse A. Pennington; Karl M. Seltzer; Paul Van Rooy; Afsara Tasnia; Barbara Barletta; Simone Meinardi; Melissa A. Ehrenfels; Andrew R. Jensen; Yuanlong Huang; Harrison A. Parker; Sina Hasheminassab; Douglas A. Day; Pedro Campuzano-Jost; Joost de Gouw; Jose L. Jimenez; Donald R. Blake; Kelley C. Barsanti; Havala O.T. Pye; John D. Crounse; Paul O. Wennberg; John H. Seinfeld

doi:10.1021/acsestair.5c00199

Complex Effects of Reduced Mobile Source Emissions on Submicron Particulate Matter Concentrations in Los Angeles

Benjamin C. Schulze
, Christopher M. Kenseth
, Ryan X. Ward
, Elyse A. Pennington
, Karl M. Seltzer
, Paul Van Rooy
, Afsara Tasnia
, Barbara Barletta
, Simone Meinardi
, Melissa A. Ehrenfels
, Andrew R. Jensen
, Yuanlong Huang
, Harrison A. Parker
, Sina Hasheminassab
, Douglas A. Day
, Pedro Campuzano-Jost
, Joost de Gouw
, Jose L. Jimenez
, Donald R. Blake
, Kelley C. Barsanti

Havala O.T. Pye, John D. Crounse, Paul O. Wennberg, John H. Seinfeld

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

Abstract

Despite considerable reductions in mobile source emissions, annual average aerosol concentrations measured in Los Angeles using Federal Reference Methods (FRM) have not appreciably declined over the past decade. Here, we use submicron aerosol measurements and zero-dimensional modeling to quantify the impacts of these emission reductions on aerosol formation in Pasadena, CA, during the late spring and summer of 2022. Reductions in secondary organic aerosol (SOA) concentrations expected from reduced mobile source emissions appear to have been largely offset by increases in hydroxyl radical concentrations, an indirect effect of reduced nitrogen oxide (NO_x) emissions. As a result, while the predicted contribution of mobile sources to the SOA burden has declined from ∼50% in 2010 to only ∼25% in 2022, concentrations of locally formed SOA have remained relatively constant. In contrast, reductions in mobile source NO_x emissions have likely reduced overnight production of nitric acid and ammonium nitrate (AN) aerosol. We provide indirect evidence that FRM measurements may have failed to capture the reduction in AN since 2010 due to the evaporation of semivolatile species from FRM filter samples. Our results suggest that given the effectiveness of historical regulatory efforts aimed at mobile sources, and on-road sources in particular, additional reductions in submicron aerosol concentrations in Los Angeles will likely require increased focus on abating emissions from nonroad and area sources.

Original language	English
Pages (from-to)	313-325
Number of pages	13
Journal	American Chemical Society Environmental Science and Technology Air
Volume	3
Issue number	2
DOIs	https://doi.org/10.1021/acsestair.5c00199
State	Published - Feb 13 2026
Externally published	Yes

Keywords

SOA
aerosol
emissions
mobile sources
nitrogen oxides

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10.1021/acsestair.5c00199

Cite this

Schulze, B. C., Kenseth, C. M., Ward, R. X., Pennington, E. A., Seltzer, K. M., Van Rooy, P., Tasnia, A., Barletta, B., Meinardi, S., Ehrenfels, M. A., Jensen, A. R., Huang, Y., Parker, H. A., Hasheminassab, S., Day, D. A., Campuzano-Jost, P., de Gouw, J., Jimenez, J. L., Blake, D. R., ... Seinfeld, J. H. (2026). Complex Effects of Reduced Mobile Source Emissions on Submicron Particulate Matter Concentrations in Los Angeles. American Chemical Society Environmental Science and Technology Air, 3(2), 313-325. https://doi.org/10.1021/acsestair.5c00199

@article{86768461ede14f68890b479de7eef953,

title = "Complex Effects of Reduced Mobile Source Emissions on Submicron Particulate Matter Concentrations in Los Angeles",

abstract = "Despite considerable reductions in mobile source emissions, annual average aerosol concentrations measured in Los Angeles using Federal Reference Methods (FRM) have not appreciably declined over the past decade. Here, we use submicron aerosol measurements and zero-dimensional modeling to quantify the impacts of these emission reductions on aerosol formation in Pasadena, CA, during the late spring and summer of 2022. Reductions in secondary organic aerosol (SOA) concentrations expected from reduced mobile source emissions appear to have been largely offset by increases in hydroxyl radical concentrations, an indirect effect of reduced nitrogen oxide (NOx) emissions. As a result, while the predicted contribution of mobile sources to the SOA burden has declined from ∼50\% in 2010 to only ∼25\% in 2022, concentrations of locally formed SOA have remained relatively constant. In contrast, reductions in mobile source NOx emissions have likely reduced overnight production of nitric acid and ammonium nitrate (AN) aerosol. We provide indirect evidence that FRM measurements may have failed to capture the reduction in AN since 2010 due to the evaporation of semivolatile species from FRM filter samples. Our results suggest that given the effectiveness of historical regulatory efforts aimed at mobile sources, and on-road sources in particular, additional reductions in submicron aerosol concentrations in Los Angeles will likely require increased focus on abating emissions from nonroad and area sources.",

keywords = "SOA, aerosol, emissions, mobile sources, nitrogen oxides",

author = "Schulze, \{Benjamin C.\} and Kenseth, \{Christopher M.\} and Ward, \{Ryan X.\} and Pennington, \{Elyse A.\} and Seltzer, \{Karl M.\} and \{Van Rooy\}, Paul and Afsara Tasnia and Barbara Barletta and Simone Meinardi and Ehrenfels, \{Melissa A.\} and Jensen, \{Andrew R.\} and Yuanlong Huang and Parker, \{Harrison A.\} and Sina Hasheminassab and Day, \{Douglas A.\} and Pedro Campuzano-Jost and \{de Gouw\}, Joost and Jimenez, \{Jose L.\} and Blake, \{Donald R.\} and Barsanti, \{Kelley C.\} and Pye, \{Havala O.T.\} and Crounse, \{John D.\} and Wennberg, \{Paul O.\} and Seinfeld, \{John H.\}",

note = "Publisher Copyright: {\textcopyright} 2025 American Chemical Society",

year = "2026",

month = feb,

day = "13",

doi = "10.1021/acsestair.5c00199",

language = "English",

volume = "3",

pages = "313--325",

journal = "American Chemical Society Environmental Science and Technology Air",

issn = "2837-1402",

publisher = "American Chemical Society",

number = "2",

}

Schulze, BC, Kenseth, CM, Ward, RX, Pennington, EA, Seltzer, KM, Van Rooy, P, Tasnia, A, Barletta, B, Meinardi, S, Ehrenfels, MA, Jensen, AR, Huang, Y, Parker, HA, Hasheminassab, S, Day, DA, Campuzano-Jost, P, de Gouw, J, Jimenez, JL, Blake, DR, Barsanti, KC, Pye, HOT, Crounse, JD, Wennberg, PO & Seinfeld, JH 2026, 'Complex Effects of Reduced Mobile Source Emissions on Submicron Particulate Matter Concentrations in Los Angeles', American Chemical Society Environmental Science and Technology Air, vol. 3, no. 2, pp. 313-325. https://doi.org/10.1021/acsestair.5c00199

TY - JOUR

T1 - Complex Effects of Reduced Mobile Source Emissions on Submicron Particulate Matter Concentrations in Los Angeles

AU - Schulze, Benjamin C.

AU - Kenseth, Christopher M.

AU - Ward, Ryan X.

AU - Pennington, Elyse A.

AU - Seltzer, Karl M.

AU - Van Rooy, Paul

AU - Tasnia, Afsara

AU - Barletta, Barbara

AU - Meinardi, Simone

AU - Ehrenfels, Melissa A.

AU - Jensen, Andrew R.

AU - Huang, Yuanlong

AU - Parker, Harrison A.

AU - Hasheminassab, Sina

AU - Day, Douglas A.

AU - Campuzano-Jost, Pedro

AU - de Gouw, Joost

AU - Jimenez, Jose L.

AU - Blake, Donald R.

AU - Barsanti, Kelley C.

AU - Pye, Havala O.T.

AU - Crounse, John D.

AU - Wennberg, Paul O.

AU - Seinfeld, John H.

PY - 2026/2/13

Y1 - 2026/2/13

N2 - Despite considerable reductions in mobile source emissions, annual average aerosol concentrations measured in Los Angeles using Federal Reference Methods (FRM) have not appreciably declined over the past decade. Here, we use submicron aerosol measurements and zero-dimensional modeling to quantify the impacts of these emission reductions on aerosol formation in Pasadena, CA, during the late spring and summer of 2022. Reductions in secondary organic aerosol (SOA) concentrations expected from reduced mobile source emissions appear to have been largely offset by increases in hydroxyl radical concentrations, an indirect effect of reduced nitrogen oxide (NOx) emissions. As a result, while the predicted contribution of mobile sources to the SOA burden has declined from ∼50% in 2010 to only ∼25% in 2022, concentrations of locally formed SOA have remained relatively constant. In contrast, reductions in mobile source NOx emissions have likely reduced overnight production of nitric acid and ammonium nitrate (AN) aerosol. We provide indirect evidence that FRM measurements may have failed to capture the reduction in AN since 2010 due to the evaporation of semivolatile species from FRM filter samples. Our results suggest that given the effectiveness of historical regulatory efforts aimed at mobile sources, and on-road sources in particular, additional reductions in submicron aerosol concentrations in Los Angeles will likely require increased focus on abating emissions from nonroad and area sources.

AB - Despite considerable reductions in mobile source emissions, annual average aerosol concentrations measured in Los Angeles using Federal Reference Methods (FRM) have not appreciably declined over the past decade. Here, we use submicron aerosol measurements and zero-dimensional modeling to quantify the impacts of these emission reductions on aerosol formation in Pasadena, CA, during the late spring and summer of 2022. Reductions in secondary organic aerosol (SOA) concentrations expected from reduced mobile source emissions appear to have been largely offset by increases in hydroxyl radical concentrations, an indirect effect of reduced nitrogen oxide (NOx) emissions. As a result, while the predicted contribution of mobile sources to the SOA burden has declined from ∼50% in 2010 to only ∼25% in 2022, concentrations of locally formed SOA have remained relatively constant. In contrast, reductions in mobile source NOx emissions have likely reduced overnight production of nitric acid and ammonium nitrate (AN) aerosol. We provide indirect evidence that FRM measurements may have failed to capture the reduction in AN since 2010 due to the evaporation of semivolatile species from FRM filter samples. Our results suggest that given the effectiveness of historical regulatory efforts aimed at mobile sources, and on-road sources in particular, additional reductions in submicron aerosol concentrations in Los Angeles will likely require increased focus on abating emissions from nonroad and area sources.

KW - SOA

KW - aerosol

KW - emissions

KW - mobile sources

KW - nitrogen oxides

UR - https://www.scopus.com/pages/publications/105031053481

U2 - 10.1021/acsestair.5c00199

DO - 10.1021/acsestair.5c00199

M3 - Article

AN - SCOPUS:105031053481

SN - 2837-1402

VL - 3

SP - 313

EP - 325

JO - American Chemical Society Environmental Science and Technology Air

JF - American Chemical Society Environmental Science and Technology Air

IS - 2

ER -

Complex Effects of Reduced Mobile Source Emissions on Submicron Particulate Matter Concentrations in Los Angeles

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