Ij. Simpson et al., MICROMETEOROLOGICAL MEASUREMENTS OF METHANE AND NITROUS-OXIDE EXCHANGE ABOVE A BOREAL ASPEN FOREST, J GEO RES-A, 102(D24), 1997, pp. 29331-29341
This paper presents tower-based measurements of methane (CH4) and nitr
ous oxide (N2O) exchange between a boreal aspen stand and the atmosphe
re. Boreal ecosystems are a priority trace gas research area, and the
work was conducted as part of the Boreal Ecosystem-Atmosphere Study (B
OREAS). Methane and nitrous oxide fluxes were measured continuously be
tween April 16 and September 16, 1994, in the Prince Albert National P
ark, Saskatchewan. The fluxes were determined using a high-resolution
tunable diode laser Trace Gas Analysis System (TGAS) together with mic
rometeorologic techniques. Both the CH4 and the N2O fluxes were small
and required long averaging times to be resolved. Over the full experi
ment, small emissions of both CH4 and N2O were measured above the aspe
n stand. The mean flux of N2O was 1.4 +/- 0.7 ng m(-2) s(-1), or 1.9-2
.5 ng m(-2) s(-1) when an enhancement factor to compensate for the bre
akdown of similarity theory just above forest canopies is included. Lo
w rates of nitrification and denitrification throughout the growing se
ason may explain the consistently small N2O fluxes. The CH4 flux avera
ged 15.7 +/- 2.8 ng m(-2) s(-1) or 21-28 ng m(-2) s(-1), including the
similarity theory enhancement factor. The CH4 emissions were highest
between late July and mid-September, and there was a strong correlatio
n between the CH4 flux and the soil temperature. Whereas CH4 emission
was measured from the above-canopy footprint, uptake was recorded clos
e to the tower base. Overall, it appears that CH4 emissions from anoxi
c wet patches located throughout the above-canopy footprint overwhelme
d uptake from drier areas to produce a net emission of CH4 from the as
pen site.