Decomposition and stabilisation of Norway spruce needle-derived material in Alpine soils using a ¹³C-labelling approach in the field

Only scarce information is available on how organic C is incorporated into the soil during the decay and how (micro) climate influences this process. Therefore, we investigated the effect of exposure and elevation on the organic litter decomposition and C-stabilisation in acidic soils of an Alpine e...

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Published in:Biogeochemistry 2016-12, Vol.131 (3), p.321-338
Main Authors: Egli, Markus, Hafner, Simon, Derungs, Curdin, Ascher-Jenull, Judith, Camin, Federica, Sartori, Giacomo, Raab, Gerald, Bontempo, Luana, Paolini, Mauro, Ziller, Luca, Bardelli, Tommaso, Petrillo, Marta, Abiven, Samuel
Format: Article
Language:English
Subjects:
Biogeosciences
Earth and Environmental Science
Earth Sciences
Ecosystems
Environmental Chemistry
Life Sciences
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Summary:Only scarce information is available on how organic C is incorporated into the soil during the decay and how (micro) climate influences this process. Therefore, we investigated the effect of exposure and elevation on the organic litter decomposition and C-stabilisation in acidic soils of an Alpine environment. An experiment with artificially ¹³C labelled Norway spruce needles was carried out at north- and south-exposed sites between 1200 and 2400 m a.s.l. in the Italian Alps using mesocosms. After 1 year, the ¹³C recoveries of the bulk soil were 18.6% at the north-facing slopes and 31.5% at the south-facing slopes. A density fractionation into a light (LF; ≤1.6 g cm⁻³) and a heavy fraction (HF; >1.6 g cm⁻³) of the soil helped to identify how the applied substrate was stabilised. At the northern slope, 10.5% of the substrate was recovered in the LF and 8.1% in the HF and at the south-facing slope 22.8% in the LF and 8.1% in the HF. The overall ¹³C recovery was higher at the south-facing sites due to restricted water availability. Although the climate is humid in the whole area, soil moisture availability becomes more important at south-facing sites due to higher evapotranspiration. However, at sites >1700 m a.s.l, the situation changed, as the northern slope had higher recovery rates. At such altitudes, temperature effects are more dominant. This highlights the importance of locally strongly varying edaphic factors when investigating the carbon cycle.
ISSN:0168-2563
1573-515X
DOI:10.1007/s10533-016-0281-x