Linking Soil Microbial Activity to Water- and Air-Phase Contents and Diffusivities

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DIVISION S-3—SOIL BIOLOGY & BIOCHEMISTRY

Linking Soil Microbial Activity to Water- and Air-Phase Contents and Diffusivities

Per Schjønning^*^,a, Ingrid K. Thomsen^a, Per Moldrup^b and Bent T. Christensen^a

^a Danish Institute of Agricultural Sciences, Department of Crop Physiology and Soil Science, Research Centre Foulum, P.O. Box 50, DK-8830 Tjele, Denmark
^b Aalborg University, Department of Environmental Engineering, Sohngaardsholmsvej 57, DK-9000 Aalborg, Denmark

* Corresponding author (per.schjonning{at}agrsci.dk)

Quantification of in situ soil microbial activity is indispensableto improve manipulation of nutrient turnover in soil and optimizecrop nutrient supply. We sampled 100-cm³ cores of undisturbedarable soil at three locations along a naturally occurring claygradient (L1: 11% clay; L3: 22% clay; L5: 34% clay). The coreswere drained to seven different matric potentials in the range-15 to -1500 hPa and gas diffusion determined prior to a 4-wkincubation at 20°C in the dark. For all soils the net nitrificationincreased with water content to a maximum (L1, 12.1 µgNO₃–N g^-1 soil; L3, 10.3 µg NO₃–N g^-1 soil;and L5, 8.2 µg NO₃–N g^-1 soil) and then decreasedwith further increase in water content. The water content atmaximum nitrification was 0.26, 0.37, and 0.42 m³ m^-3, respectively.Calculations of water-filled pore space (WFPS) did not normalizesoil type differences in optima for microbial activity. Thematric potential at peak net nitrification was -140, -170, and-430 hPa, respectively. No single correlation between CO₂ evolutionand soil water content existed across soil types. The relativesolute diffusivity estimated by recently developed models offereda better description of CO₂ evolution. The relative gas diffusivitywas a better predictor of the increase in net nitrificationthan was the soil air content. A conceptual model balancingthe effects of solute and gas diffusivity indicated that therelative trend in the observed optima of water contents acrosssoil types was as expected. We advocate the use of the conceptualmodel including soil type dependent expressions for solute andgas diffusivity in future studies of aerobic microbial activity.

Abbreviations: BBC, Buckingham-Burdine-Campbell • BET, Brunauer-Emmett-Teller • CEC, cation-exchange capacity • ODR, oxygen diffusion rate • SA, surface area • WFPS, water-filled pore space

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