Tropospheric OH in a three‐dimensional chemical tracer model: An assessment based on observations of CH 3 CCl 3

The three‐dimensional global distribution of OH over a year is calculated as a function of temperature, ultraviolet irradiance, and densities of H 2 O, CO, O 3 , CH 4 , and NO t , (defined as NO + NO 2 + NO 3 + 2N 2 O 5 + HNO 2 + HNO 4 ). The concentration of OH is computed within a chemical tracer model (CTM) with an accuracy comparable to that of a detailed photochemical model. Distributions of CO, NO t , O 3 , CH 4 , and the density of O 3 column were specified on the basis of observations. Meteorological fields were derived from the general circulation model developed at the Goddard Institute for Space Studies. The numerical method for parametrization of chemistry is described in Spivakovsky et al. (this issue). The CTM is used to simulate the global distribution of CH 3 CCl 3 . The computed distribution of OH implies a lifetime of 5.5 years for CH 3 CCl 3 (obtained by relating the global burden of CH 3 CCl 3 to the global loss, integrated using simulated three‐dimensional distributions). Analysis of the long‐term trend in CH 3 CCl 3 as defined by observations suggests a lifetime of 6.2 years (consistent with Prinn et al. (1987)), indicating that model levels of OH may be too high by about 13%. This estimate for the lifetime depends on industry data for global emissions and on the absolute calibration of observations. It is argued that seasonal variations of CH 3 CCl 3 provide an independent test for computed OH fields that is insensitive to the uncertainties in the budget of CH 3 CCl 3 . The annual cycle of CH 3 CCl 3 from about 25°S to the South Pole is dominated by seasonal changes in OH. Observed seasonal variations of CH 3 CCl 3 indicate that the OH field south of 20°S±4° should be scaled by 0.75±0.25 from computed values, consistent with the result based on long‐term trends. Reactions involving non‐methane hydrocarbons were not included in the current model. These reactions could account for lower concentrations of OH than computed. Seasonal variations of CH 3 CCl 3 in the tropics and in the northern mid‐latitudes are dominated by effects of transport. If use of CH 3 CCl 3 is phased out (as envisioned by the Montreal protocol), the dynamically driven seasonal variations of CH 3 CCl 3 will decrease dramatically, whereas the chemically driven variations will remain proportional to the concentration of CH 3 CCl 3 ; then the annual cycle of CH 3 CCl 3 in northern mid‐latitudes will provide a measure of OH as does at present the annual cycle in southern mid‐latitudes. The influence of chemistry on the latitudinal distribution of CH 3 CCl 3 is small and at present does not provide a constraint for the globally averaged OH or for the latitudinal distribution of OH. However, if emissions of CH 3 CCl 3 were to cease, the tropical depression in the concentration of CH 3 CCl 3 caused by high levels of OH in the tropics may provide an additional means to test OH models.