Abstract

The global influence on tropospheric chemistry of nitrogen oxides (NO x = NO + NO 2 ) emitted by fossil fuel combustion may be strongly modulated by nonmethane hydrocarbon (NMHC) chemistry taking place in the continental boundary layer. This effect is investigated using a three‐dimensional, continental‐scale model of tropospheric O 3 ‐NO x ‐NMHC chemistry over North America in summer. The model includes detailed representation of NMHC chemistry including in particular isoprene. Model results are evaluated with observations for ozone, reactive nitrogen species, and photochemical tracers at a number of sites in North America. Sensitivity analyses are conducted to explore the effects of assumptions regarding the aerosol chemistry of peroxy radicals and the fate of hydroxy organic nitrates produced from the oxidation of isoprene. A budget analysis for the United States in the model indicates that 9% Of NO x . emitted from fossil fuel combustion is exported out of the continental boundary layer as NO x , 3.5% is exported as peroxyacetyl nitrate (PAN), and 3.7% is exported as other organic nitrates. Isoprene is the principal NMHC responsible for the formation and export of organic nitrates, which eventually decompose to provide a source of NO x in the remote troposphere. Export of NO x . and organic nitrates from the U.S. boundary layer is found to be a major source of NO x . on the scale of the northern hemisphere troposphere and on the scale of the upper troposphere at northern midlatitudes. Proper representation of isoprene chemistry in the continental boundary layer is important for simulation Of NO x in global tropospheric chemistry models.