SSSAJ Journal of Natural Resources and Life Sciences Education
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Soil Science Society of America Journal 65:1529-1538 (2001)
© 2001 Soil Science Society of America


DIVISION S-7 - FOREST & RANGE SOILS & CONSERVATION

Carbon and Nitrogen Dynamics in Preferential Flow Paths and Matrix of a Forest Soil

Maya Bundt*,a, Maya Jäggib, Peter Blasera, Rolf Siegwolfb and Frank Hagedorna

a Swiss Federal Institute for Forest, Snow, and Landscape Research (WSL), Zürcherstr. 111, CH 8903 Birmensdorf
b Paul Scherrer Institute, 5232 Villigen-PSI

* Corresponding author (bundt{at}wsl.ch)

Natural abundance ({delta}) of the stable isotopes 13C and 15N has gained acceptance for studying C and N cycling in forests. In most studies, bulk soil samples are collected to determine isotope abundance. Such sampling overlooks the potential impact of preferential flow on isotope distribution. The objective of this study was to investigate the effects of preferential flow on the distribution of soil organic carbon (SOC), total N, {delta}13C, and {delta}15N in a forest soil in Central Switzerland. Preferential flow paths in the soil were identified with a dye tracer, Brilliant Blue (Plüss-Staufer AG, Oftringen, Switzerland), that was homogeneously applied to the soil surface. In the stained preferential flow paths, concentrations of SOC and total N were 15 to 75% higher than in the soil matrix. The total increase of SOC in preferential flow paths ranged from 740 to 960 g C m-2 in four individual soil plots. Values of {delta}13C and {delta}15N were lowest in tree leaves and in the forest floor, and increased with soil depth, thus with the degree of decomposition of SOC. In the mineral soil, preferential flow paths were significantly depleted in 13C by 0.15 to 0.4{per thousand} as compared with the soil matrix. The {delta}15N values increased with soil depth from 0.9 to 4.7{per thousand} in the preferential flow paths and from 0.5 to 6{per thousand} in the soil matrix. Adding a highly enriched 15N-tracer homogeneously to the soil surface showed a higher recovery of 15N in the soil and in the fine roots sampled from preferential flow paths than in those sampled from the soil matrix. Our results suggest that in preferential flow paths, SOC is younger and N cycling is more rapid than in the soil matrix.

Abbreviations: DOC, dissolved organic carbon • SOC, soil organic carbon • SOM, soil organic matter • Corg, organic carbon • {delta}, natural abundance






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