Dependencies and sensitivity of tropospheric oxidants to precursor concentrations over the Northeast United States: A model study

Abstract

Atmospheric distribution of photochemical oxidants has been a subject of interest and concern not only because of their deleterious effects on human health and vegetation but also because of their crucial role in determining the chemical composition of the atmosphere. Several important issues related to the distribution and production of photochemical species are examined through an analysis of results obtained from applications of a comprehensive three‐dimensional regional scale photochemical model over the Northeast United States. The Regional Oxidant Model (ROM) is used to simulate the response of various photochemical species to specific anthropogenic emission strategies involving NO_x, and hydrocarbon reductions for an episodic period during July 1988. Domain and temporal averages of predicted concentrations are examined for various species. Their relative influence on oxidant chemistry over the modeled domain is investigated. Further, spatial distributions of O₃ with respect to those of NO_x, NO_y, and hydrocarbons over the modeled domain are examined and the variations in O₃ levels for different chemical regimes classified by characteristic NO_x/reactive organic gases and NO_x/NO_y ratios are investigated. Temporal trends in domain‐averaged concentrations indicate that the model replicates the expected diurnal trends in species concentrations. The relative benefits of reductions in NO_x and hydrocarbon emissions on predicted O₃ levels are also examined. In general, for this modeled domain, reductions in NO_x emissions with or without reductions in hydrocarbon emissions have more impact on reducing predicted O₃ levels compared to reductions only in hydrocarbon emissions.