The University of Arizona
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Using (super 14) C as a tracer of carbon accumulation and turnover in soils.

G M Milton, S J Kramer


Three very different Canadian soils--clay soils of the St. Lawrence Lowlands, sandy forest soils of the Ottawa Valley, and organic-rich sediments from a wetland on the Canadian Shield--have been cored, sliced and separated into different density fractions, and the radiocarbon content of these soil fractions measured. In two of the areas sampled, cores were obtained close to operating nuclear reactors, as well as from beyond their region of influence. As a consequence, it has been possible to ascertain the depths of penetration of both the weapons-testing pulse (peaking in 1963), and a 25-50-yr chronic reactor input of (super 14) C. The percentage of carbon stored in different density fractions varied with soil type. Turnover times for bulk soil organic carbon, estimated from soil degassing rates, have been compared with those predicated on the residual "bomb" (super 14) C in background cores, and/or on the ratio of reactor-emitted (super 14) C retained in the soils to the total deposited during the lifetime of operation. Residence times for the heavy carbon fraction present at depths below the influence of anthropogenic inputs have also been estimated. The accumulated data will be incorporated in a revised soil model, adjusted for the parameters deemed to be most important to carbon turnover rates under Canadian conditions.


Canadian Shield;Chalk River Ontario;Durham County Ontario;Nipissing District Ontario;Ottawa Valley;Pickering Nuclear Generating Station;Pickering Ontario;Renfrew County Ontario;Saint Lawrence Lowlands;Sturgeon Falls Ontario;nuclear facilities;fallout;Eastern Canada;Ontario;land use;North America;residence time;tracers;carbon cycle;geochemical cycle;cores;Canada;human activity;soils;C 14;carbon;isotopes;radioactive isotopes

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