Possible perturbations to atmospheric CO, CH4, and OH

Abstract

A photochemical model is used to predict temporal trends in OH, CH₄, and CO over the next 50 years and to assess possible past changes in these trace gases from 1860 to 1985. Various scenarios of perturbed CH₄ and CO levels based on recently reported CH₄ and CO data are simulated at several levels of background NO_x. With low NO_x conditions (NO + NO₂ = 25 pptv (parts per trillion by volume)), typical of the nonpolluted troposphere, we compute a monotonic loss of tropospheric OH from 1860 to 2035, with the magnitude of the decrease dependent on CO and CH₄ increases during the period. If current trends continue (ground‐level mixing ratios (mole fractions) of CH₄ rising about 1% per year), by 2035 northern latitude CH₄ will increase from 1.6 to 2.9 ppmv (parts per million by volume) and CO will double or triple its present day level (to about 250–350 ppbv (parts per billion by volume) in the nonpolluted northern hemisphere). The column abundance of OH in the background troposphere will decrease 25–35%, depending on the magnitude of CH₄ and CO increases and assuming that global temperature increases do not raise water vapor levels during that time. Calculations with increased H₂O show a 17–30% decrease in OH. Under higher‐NO_x conditions (1 ppbv), OH shows a decline from 1860 to 2035, but it shows only half as much decline as with low‐NO_x conditions. In the case of NO_x in a transitional zone (i.e., NO_x increasing from 20 pptv in 1860 to 0.5 ppbv in 2035), CO and CH₄ increases accompany a rise in OH, followed by a small decline. The turning point in OH depends on the rate of change in NO_x and O₃. Recently observed upward trends in CO and CH₄ are probably due to increasing emissions of both CH₄ and CO. We always compute a temporal increase in tropospheric O₃ when CH₄ and CO increase. Typical 1860 values for surface O₃ are 25 ppbv, compared to 30 ppbv (NO_x = 25 pptv)and 40 ppbv (NO_x = 1 ppbv) in 1985. In a transition NO_x zone we find surface O₃ increasing from 10 ppbv in 1860 to 27 ppbv in 1985.