ATMOSPHERIC CO2 CONSUMPTION BY CONTINENTAL EROSION - PRESENT-DAY CONTROLS AND IMPLICATIONS FOR THE LAST GLACIAL MAXIMUM

The export of carbon from land to sea by rivers represents a major lin k in the global carbon cycle, For all principal carbon forms, the main factors that control the present-day fluxes at the global scale have been determined in order to establish global budgets and to predict re gional fluxes. Dissolved organic carbon fluxes are mainly related to d rainage intensity, basin slope, and the amount of carbon stored in soi ls. Particulate organic carbon fluxes are calculated as a function of sediment yields and of drainage intensity. The consumption of atmosphe ric/soil CO2 by chemical rock weathering depends mainly on the rock ty pe and on the drainage intensity. Our empirical models yield a total o f 0.721 Gt of carbon (Gt C) that is exported from the continents to th e oceans each year. From this figure, 0.096 Gt C come from carbonate m ineral dissolution and the remaining 0.625 Gt C stem from the atmosphe re (F-CO2). Of this atmospheric carbon, 33% is discharged as dissolved organic carbon, 30% as particulate organic carbon, and 37% as bicarbo nate ions. Predicted inorganic carbon fluxes were further compared wit h observed fluxes for a set of 35 major world rivers, and possible add itional climatic effects on the consumption of atmospheric CO2 by rock weathering were investigated in these river basins. Finally, we discu ss the implications of our results for the river carbon fluxes and the role of continental erosion in the global carbon cycle during the las t glacial maximum. (C) 1998 Elsevier Science B.V. All rights reserved.