Abstract
We use the natural radionuclides 7Be and 210Pb as aerosol tracers in a three‐dimensional chemical tracer model (based on the Goddard Institute for Space Studies general circulation model (GCM) 2) in order to study aerosol transport and removal in the troposphere. Beryllium 7, produced in the upper troposphere and stratosphere by cosmic rays, and 210Pb, a decay product of soil‐derived 222Rn, are tracers of upper and lower tropospheric aerosols, respectively. Their source regions make them particularly suitable for the study of vertical transport processes. Both tracers are removed from the troposphere primarily by precipitation and are useful for testing scavenging parameterizations. In particular, model convection must properly transport and scavenge both ascending 210Pb and descending 7Be. The ratio 7Be/210Pb cancels most model errors associated with precipitation and serves as an indicator of vertical transport. We show that over land the annual average 7Be/210Pb ratio for surface concentrations and deposition fluxes vary little globally. In contrast, the seasonal variability of the 7Be/210Pb concentration ratio over continents is quite large; the ratio peaks in summer when convective activity is maximum. The model overestimates 7Be in the tropics, a problem which we relate to flaws in the GCM parameterization of wet convection (excessive convective mass fluxes and no allowance for entrainment). The residence time of tropospheric 7Be calculated by the model is 23 days, in contrast with a value of about 9 days calculated for 210Pb, reflecting the high‐altitude versus low‐altitude source regions of these two tracers.
Highlights
Introduction opedattheGoddardInstituteforSpaceStudies(GISS).The transport and persistenceof troposphericaerosolsBeryllium 7 and lead 210 are natural radionuclide is a matter of growingconcern,sinceanthropogenicsultracersof aerosolsoriginatingover a rangeof altitudes fate contributionsto the aerosolbudgetmay play a sigin theatmosphereT.akentogether*,Beand21øpbyield nificantrolein recentclimatechanges[Ckarlsoret el., information on vertical motions in the atmosphereand 1991,1992].Mostof the aerosool pticaldepthis in the the scavengingof aerosols.We investigatein this pa- lowertroposphere.,Clarke[1992]foundthat per the factorscontrollingthe atmosphericdistributions formationof newparticles(e.g.,by SO gasto particle of *Be and21øPbby usinga globalthree-dimensionaclonversioni)s mostlikely to occurin the upper trochemicatlracermodel(CTM) drivenby meteorologicalpospherewhere the aerosolmass is low
We will showthat this added scavenging x longitude)w, ith nineverticallayers(seeFigure1). improvetshesimulatioinn thetropicsforbothVBeand
The overall model bias for the ?Be The model surface concentrations are maximum near depositionflux, basedon the data shownin Figure 6, is the equatorand overcontinents.The higher concentra
Summary
“Vertical Transport of Tropospheric Aerosols as Indicated by 7 Be and 210 Pb in a Chemical Tracer Model.”. Journal of Geophysical Research 101 (D13): 18651. Vertical transport of tropospheric aerosols as indicated by and in a chemical tracer model. Jacob Department of Earth and Planetary Sciencesand Division of Applied SciencesH, arvard University, Cambridge, Massachusetts. Graustein Department of Geologyand Geophysics,Yale University, New Haven, Connecticut
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