posted on 2025-01-11, 02:43authored byCam M. Phelan, Abiola S. Lawal, Jacob Boomsma, Kamaljeet Kaur, Kerry E. Kelly, Heather A. Holmes, Cesunica E. Ivey
Chemical transport
models are used for federal compliance demonstrations
when areas are out of attainment, but there is no guidance for choosing
a chemical mechanism. With the 2024 change of the annual PM2.5 standard and the prevalence of multiday wintertime inversion episodes
in the western U.S., understanding the wintertime performance of chemical
transport models is important. This study explores the impact of chemical
mechanism choice on the Community Multiscale Air Quality (CMAQ) model
performance for PM2.5 and implications for attainment demonstration
in inversion-prone areas in the western United States. Total and speciated
PM2.5 observations were used to evaluate wintertime CMAQ
simulations using four chemical mechanisms. The study evaluated intermechanism
differences in total and secondary PM2.5 and the impact
of meteorology at sites with observed multiday temperature inversions.
Model performance for total PM2.5 was similar across chemical
mechanisms, but intermechanism differences for total and secondary
PM2.5 were exacerbated during inversion periods, suggesting
that modeled chemistry contributes to the model bias. Results suggest
that nitrate, ammonium, and organic carbon are secondary species for
which model results do not agree or perform to standard evaluation
metrics in scientific literature. These findings show a need for mechanistic
investigations of the causes of these differences.