Spatial and temporal variations in hectare-scale net CO_2 flux, respiration and gross primary production of Arctic tundra ecosystems

摘要

1. Eddy covariance was used to measure the net CO_2 flux of Alaskan moist-tussock and wet-sedge tundra ecosystems between 1 June and 31 August 1995. The sites were located within 2.5 km of each other and, depending on wind speed and thermal stability, the eddy-covariance measurements integrated surface fluxes over 0.8-26.5 ha (mean 3.8 ha) at the moist-tussock site and 0.1-4.2 ha (mean 0.6) at the wet-sedge site. 2. Both were net sinks for atmospheric CO_2 during the 92-day measurement period but wet-sedge tundra accumulated 1.5 times more CO_2 than moist-tussock tundra. Wet-sedge tundra was a net CO_2 sink of -6.4 mol m~-2 and moist-tussock tundra was a net sink of -4.6 mol m~-2 over the June-August measurement period. 3. Estimates of whole-ecosystem respiration (R) were made using multiple non-linear regression by quantifying the response of measured nocturnal CO_2 efflux (F_n) to fluctuations in air temperature and water-table depth (r~2 = 0.68). Partial regression analysis revealed that water-table depth explained relatively more of the variance in F_n (45%) than temperature (11%). R was estimated to be 14.9 mol m~-2 for moist-tussock tundra and 5.4 mol m~-2 for wet-sedge tundra over the 92-day measurement period. The large difference in R was apparently owing to a substantially higher water table in wet-sedge tundra. 4. Estimated rates of gross primary production (GPP), calculated from measured net CO_2 flux and estimated R, were 40% lower for wet-sedge tundra over the 92-day measurement period. Rates of GPP integrated over diel (24 h) periods were substantially larger for moist-tussock tundra ecosystems throughout June and July but during the month of August, total diel rates of GPP for moist-tussock and wet-sedge tundra were comparable. 5. Our results demonstrate that R and GPP of moist-tussock and wet-sedge tundra ecosystems can be reliably from eddy-covariance measurements using functional relativeships developed from plot-scale studies. Given the large spatial differences in hydrology, the larger sink observed for wet-sedge tundra was probably the result of relatively lower rates of R.