Elevated atmospheric CO2 has the potential to change below-ground nutrient
cycling and thereby alter the soil-atmosphere exchange of biogenic trace ga
ses. We measured fluxes of CH4 and N2O in trembling aspen (Populus tremuloi
des Michx.) stands grown in open-top chambers under ambient and twice-ambie
nt CO2 concentrations crossed with `high' and low soil-N conditions.
Flux measurements with small static chambers indicated net CH4 oxidation in
the open-top chambers. Across dates, CH4 oxidation activity was significan
tly (P < 0.05) greater with ambient CO2 (8.7 mu g CH4-C m(-2) h(-1)) than w
ith elevated CO2 (6.5 mu g CH4-C m(-2) h(-1)) in the low N soil. Likewise,
across dates and soil N treatments CH4 was oxidized more rapidly (P < 0.05)
in chambers with ambient CO2 (9.5 mu g CH4-C m(-2) h(-1)) than in chambers
with elevated CO2 (8.8 mu g CH4-C m(-2) h(-1)). Methane oxidation in soils
incubated in serum bottles did not show any response to the CO2 treatment.
We suggest that the depressed CH4 oxidation under elevated CO2 in the fiel
d chambers is due to soil moisture which tended to be higher in the twice-a
mbient CO2 treatment than in the ambient CO2 treatment.
Phase I denitrification (denitrification enzyme activity) was 12-26% greate
r under elevated CO2 than under ambient CO2 in the `high' N soil; one sampl
ing, however, showed a 39% lower enzyme activity with elevated CO2. In both
soil N treatments, denitrification potentials measured after 24 or 48 h we
re between 11% and 21% greater (P < 0.05) with twice-ambient CO2 than with
ambient CO2. Fluxes of N2O in the open-top chambers and in separate 44 cm(2
) cores +/-N fertilization were not affected by CO2 treatment and soil N st
atus.
Our data show that elevated atmospheric CO2 may have a negative effect on t
errestrial CH4 oxidation. The data also indicated temporary greater denitri
fication with elevated CO2 than with ambient CO2. In contrast, we found no
evidence for altered fluxes of N2O in response to increases in atmospheric
CO2.