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Decreases in Epoxide-Driven Secondary Organic Aerosol Production under Highly Acidic Conditions: The Importance of Acid-Base Equilibria.

Madeline E CookeN Cazimir ArmstrongAlison M FankhauserYuzhi ChenZiying LeiYue ZhangIsabel R LedskyBarbara J TurpinZhenfa ZhangAvram GoldV Faye McNeillJason D SurrattAndrew P Ault
Published in: Environmental science & technology (2024)
Isoprene has the highest atmospheric emissions of any nonmethane hydrocarbon, and isoprene epoxydiols (IEPOX) are well-established oxidation products and the primary contributors forming isoprene-derived secondary organic aerosol (SOA). Highly acidic particles (pH 0-3) widespread across the lower troposphere enable acid-driven multiphase chemistry of IEPOX, such as epoxide ring-opening reactions forming methyltetrol sulfates through nucleophilic attack of sulfate (SO 4 2- ). Herein, we systematically demonstrate an unexpected decrease in SOA formation from IEPOX on highly acidic particles (pH < 1). While IEPOX-SOA formation is commonly assumed to increase at low pH when more [H + ] is available to protonate epoxides, we observe maximum SOA formation at pH 1 and less SOA formation at pH 0.0 and 0.4. This is attributed to limited availability of SO 4 2- at pH values below the acid dissociation constant (p K a ) of SO 4 2- and bisulfate (HSO 4 - ). The nucleophilicity of HSO 4 - is 100× lower than SO 4 2- , decreasing SOA formation and shifting particulate products from low-volatility organosulfates to higher-volatility polyols. Current model parameterizations predicting SOA yields for IEPOX-SOA do not properly account for the SO 4 2- /HSO 4 - equilibrium, leading to overpredictions of SOA formation at low pH. Accounting for this underexplored acidity-dependent behavior is critical for accurately predicting SOA concentrations and resolving SOA impacts on air quality.
Keyphrases
  • ionic liquid
  • water soluble
  • molecular dynamics simulations
  • heavy metals