Long-term observation of the atmospheric exchange of CO2 with a temperate deciduous forest in southern Ontario, Canada

This paper reports the results of the analysis of eddy covariance CO2 data obtained at a successional forest of maple and aspen at Camp Borden in sout hern Ontario, Canada, between July 1995 and December 1997. Main findings ar e (1) The Michaelis-Menton model explains >50-65% of the observed variance of the daytime net ecosystem carbon exchange (NEE) during the growing seaso n; leaf wetness appears to be an important variable contributing to the rem aining variance. (2) The whole-ecosystem respiration rate as a function of the 5-cm soil temperature shows a seasonal "hysteresis" (higher rate in the later part of the year), suggesting a nonnegligible contribution by deep s oil/roots and the influence of litter age. (3) There is evidence of photosy nthetic activities immediately after the spring snowmelt/soil warming, but the. daily NEE did not switch sign till about 40 days later; our best estim ates of the annual net carbon uptake by the ecosystem net ecosystem product ion (NEP) are -1,0, -1.2, and -2.8 t C ha(-1) yr(-1) for the periods July 1 9, 1995, to July 18, 1996, January 1 to December 31, 1996, and January 1 to December 31, 1997, respectively, with an uncertainty of +/-0.4 t C ha(-1) yr(-1). (4) The higher NEP value in 1997 than in 1996 was caused by lower g rowing season soil temperature, cooler spring and fall transitional periods , and higher photon flux in 1997; possible enhancement in canopy photosynth etic capacity may also have played a role. In addition, three main sources of uncertainties, data gap, fetch, and mass flow, are discussed, it is sugg ested that collective use of the methods available for assessing the whole- ecosystem respiration (friction velocity threshold, mass flow theory, and d ark respiration from the forest light response) may increase the confidence level of NEP estimates.