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The effect of permafrost on time-split soil erosion using radionuclides (137Cs, 239+240Pu, meteoric 10Be) and stable isotopes (13C) in the Eastern Swiss Alps
JournalArticle (Originalarbeit in einer wissenschaftlichen Zeitschrift)
ID
2644703
Author(s)
Zollinger, Barbara; Alewell, Christine; Kneisel, Christof; Meusburger, Katrin; Brandová, Dagmar; Kubik, Peter; Schaller, Mirjam; Ketterer, Michael E.; Egli, Markus
The effect of permafrost on time-split soil erosion using radionuclides (137Cs, 239+240Pu, meteoric 10Be) and stable isotopes (13C) in the Eastern Swiss Alps
Journal
Journal of soils and sediments
Volume
15
Number
6
Pages / Article-Number
1400-1419
Abstract
Purpose
Global warming is expected to change the thermal and hydrological soil regime in permafrost ecosystems which might impact soil erosion processes. Erosion assessment using radionuclides can provide information on past and ongoing, i.e. time-split, processes. The focus of this work was to find out if permafrost soils in the Swiss Alps differ in their medium- and long-term erosion rates from non-permafrost soils and if rates have accelerated during the last few decades.
Materials and methods
Using cosmogenic (meteoric 10Be) and anthropogenic radionuclides (137Cs, 239 + 240Pu), a time-split approach was achieved by determining erosion activities on the long (millennia; 10Be) and medium term (decades; 137Cs, 239 + 240Pu). Additionally, the stable isotope δ13C signature in soil organic matter was used as a qualitative indicator for soil disturbance patterns. We compared soil erosion processes in permafrost soils and nearby unfrozen soils in the alpine (sites at 2,700 m asl, alpine tundra) and the subalpine (sites 1,800 m asl, natural forest) range of the Swiss Alps (Upper Engadine). 137Cs, 239 + 240Pu and δ13C measurements were performed at the alpine sites only.
Results and discussion
Depending on the calculation procedure (profile distribution model or inventory method), the 137Cs measurements revealed soil accumulation rates of 1–3 t/km2/year in permafrost soils and 34–52 t/km2/year in non-permafrost soils. However, due to snow cover and subsequent melt-water runoff during 137Cs deposition after the Chernobyl accident, caesium does not seem to be an appropriate soil erosion tracer on the investigated alpine sites. With 239 + 240Pu, more reliable results were achieved. 239 + 240Pu measurements provided erosion rates of 31–186 t/km2/year in permafrost soils and accumulation rates of 87–218 t/km2/year in non-permafrost soils. Erosion and accumulation were relatively low and related to the vegetation community. The long-term (10Be) soil redistribution rates (erosion rates up to 49 t/km2/year and accumulation rates up to 4 t/km2/year) were low with no significant differences between permafrost and non-permafrost sites. The δ13C signature indicated soil disturbances in permafrost and non-permafrost soils compared to the reference site.
Conclusions
Our results highlight that soil redistribution rates have increased during the last few decades. However, whether the higher medium-term erosion rates obtained for the last decades are the result of the ongoing climate warming and related accelerated soil erosion or if other factors (e.g. measurement uncertainties) have been responsible for such an increase could not fully be clarified.
