Increasing Contributions of Temperature-Dependent Oxygenated Organic Aerosol to Summertime Particulate Matter in New York City

Overview

Journal ACS EST Air

Publisher American Chemical Society

Date 2024 Sep 23

PMID 39309979

Authors

Tori Hass-Mitchell

Taekyu Joo

Mitchell Rogers

Benjamin A Nault

Catelynn Soong

Mia Tran

Minguk Seo

Jo Ellen Machesky

Manjula Canagaratna

Joseph Roscioli

Megan S Claflin

Brian M Lerner

Daniel C Blomdahl

Pawel K Misztal

Nga L Ng

Ann M Dillner

Roya Bahreini

Armistead Russell

Jordan E Krechmer

Andrew Lambe

Drew R Gentner

Affiliations

Soon will be listed here.

Abstract

As part of the summer 2022 NYC-METS (New York City metropolitan Measurements of Emissions and TransformationS) campaign and the ASCENT (Atmospheric Science and Chemistry mEasurement NeTwork) observational network, speciated particulate matter was measured in real time in Manhattan and Queens, NY, with additional gas-phase measurements. Largely due to observed reductions in inorganic sulfate aerosol components over the 21st century, summertime aerosol composition in NYC has become predominantly organic (80-83%). Organic aerosol source apportionment via positive matrix factorization showed that this is dominated by secondary production as oxygenated organic aerosol (OOA) source factors comprised 73-76% of OA. Primary factors, including cooking-related organic aerosol (COA) and hydrocarbon-like organic aerosol (HOA) comprised minor fractions of OA, only 13-15% and 10-11%, respectively. The two sites presented considerable spatiotemporal variations in OA source factor concentrations despite similar average PM concentrations. The less- and more-oxidized OOA factors exhibited clear temperature dependences at both sites with increased concentrations and greater degrees of oxidation at higher temperatures, including during a heatwave. With strong temperature sensitivity and minimal changes in summertime concentrations since 2001, secondary OA poses a particular challenge for air quality policy in NYC that will very likely be exacerbated by continued climate change and extreme heat events.

Citing Articles

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