Abstract. Soil respiration (Rs), the flow of CO2 from the soil
surface to the atmosphere, is one of the largest carbon fluxes in the
terrestrial biosphere. The spatial variability of Rs is both large and
poorly understood, limiting our ability to robustly scale it in space. One
factor in Rs spatial variability is the autotrophic contribution from
plant roots, but it is uncertain how the presence of plants affects the
magnitude and temperature sensitivity of Rs. This study used 1 year of Rs measurements to examine the effect of localized basal area on
Rs in the growing and dormant seasons, as well as during
moisture-limited times, in a temperate, coastal, deciduous forest in eastern
Maryland, USA. In a linear mixed-effects model, tree basal area within a 5 m
radius (BA5) exerted a significant positive effect on the temperature
sensitivity of soil respiration. Soil moisture was the dominant control on
Rs during the dry portions of the year, while soil moisture,
temperature, and BA5 all exerted significant effects on Rs in
wetter periods. Our results suggest that autotrophic respiration is more
sensitive to temperature than heterotrophic respiration at these sites,
although we did not measure these source fluxes directly, and that soil
respiration is highly moisture sensitive, even in a record-rainfall year.
The Rs flux magnitudes (0.46–15.0 µmol m−2 s−1) and
variability (coefficient of variability 10 %–23 % across plots) observed
in this study were comparable to values observed in similar forests. Six
Rs observations would be required in order to estimate the mean across
all study sites to within 50 %, and 518 would be required in order to
estimate it to within 5 %, with 95 % confidence. A better understanding
of the spatial interactions between plants and microbes, as well as the
strength and speed of above- and belowground coupling, is necessary to
link these processes with large-scale soil-to-atmosphere C fluxes.
Spatial variations of soil respiration and temperature sensitivity along a steep slope of the semiarid Loess Plateau