Abstract
The response of vegetation growth to fluctuations in climate or anthropogenic influences is an important consideration in the evaluation of the contribution of land biota to atmospheric CO2 variations. Here we present two approaches to investigate the role of boreal forests in the global carbon cycle. First, a tracer transport model wihich incorporates the normalized-difference vegetation index (NDVI) obtained from advanced very high resolution radiometer (AVHRR) radiances was used to simulate the annual cycle of CO2 in the atmosphere. Results indicate that the seasonal growth of the combined boreal forests of North America and Eurasia accounts for about 50% of the mean seasonal CO2 amplitude recorded at Pt Barrow, Alaska (71° N, 157° W) and about 30% of the more globally representative CO2 signal at Mauna Loa, Hawaii (20° N, 156° W). Second, tree-ring width data from four boreal treeline sites in northern Canada were positively correlated with Pt Barrow CO2 drawdown (that is, maximum–minimum CO2 concentration) for the period 1971–1982. These results suggest that large-scale changes in the growth of boreal forests may be contributing to the observed increasing trend in CO2 amplitude. They further suggest that tree-ring data may be applicable as indices for CO2 uptake and remote sensing estimates of photosynthetic activity.
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