Final Report Abstract

In mountain ecosystems, elevation, slope exposure, and a highly heterogeneous relief cause a high spatial variability of microclimate, soil moisture regimes, and patterns of erosion and accumulation. As a consequence, distribution patterns of humus forms as well as of soil organisms show a high spatial variability. Spatial information on humus forms is scarce especially in mountain areas, and studies on soil biodiversity are usually limited to the local scale. Within the D.A.CH. project “Effect of climate on coarse woody debris decay dynamics and incorporation into the soils of forested Alpine areas (DecAlp)” we studied natural subalpine coniferous forest ecosystems in two alpine valleys (Val di Sole, Val di Rabbi) in Trentino, Italian Alps, between ca. 1200 and 1800 m a.s.l. The aim of our Working Group “Modelling” was I. to predict the spatial distribution of humus forms as a function of environmental characteristics and II. to use humus forms as proxy for soil biota (specifically enchytraeids and microorganisms) for spatial extrapolation. Our first goal was to establish a suitable technique for the spatial modelling of humus forms. We achieved this by using a combination of classification and regression trees (CART) and fuzzy membership functions. Based on topographic data, we created prediction maps of humus form patterns depending on elevation and exposure. Moreover, we assessed the quality of various vegetation parameters as bioindicators of humus forms. Mean Landolt indicator values of the herb layer (especially the indicator value for soil reaction) displayed a close relationship with humus form properties. Furthermore, we addressed the influence of the spatial scale on humus form modelling. We considered the varying influences by elevation, microtopography and vegetation during the implementation of humus form models at the local, the slope, and the landscape scale, resulting in simulations and prediction maps of humus forms. Another part of the project dealt with humus forms as proxy of the soil biota distribution from the plot scale to the landscape scale. We modelled the spatial distribution of mull-indicating enchytraeids and of moder/mor-indicating enchytraeids and compared these prediction maps with those of humus forms. There was a strong link between the spatial distribution of humus forms and the occurrence of certain groups of enchytraeid species, which is consistent across the major part of our study area. Thus, we have shown that humus forms can be used as a proxy of the decomposer community in our study area. Humus form models and derived models of the decomposer community have great potential as tool to detect environmental conditions in mountain ecosystems and their changes, e. g. with respect to soil quality, carbon stocks, and growing conditions for plants.

Publications

• (2017) Vegetation-based bioindication of humus forms in coniferous mountain forests. J. Mt. Sci. (Journal of Mountain Science) 14 (4) 662–673
  Anschlag, Kerstin; Tatti, Dylan; Hellwig, Niels; Sartori, Giacomo; Gobat, Jean-Michel; Broll, Gabriele
  (See online at https://doi.org/10.1007/s11629-016-4290-y)
• (2015) GIS-basierte Modellierung von Humusformen und Enchyträen in zwei italienischen Alpentälern. In: Berichte der DBG (eprints), Unsere Böden – Unser Leben (Annual Meeting of the German Soil Science Society), 5-10/09/2015, München
  Hellwig N, Graefe U, Tatti D, Anschlag K, Gobat J-M, Broll, G
  
• (2016) A fuzzy logic based method for modeling the spatial distribution of indicators for decomposition in a high mountain environment. Arctic, Antarctic, and Alpine Research 48: 623-635
  Hellwig N, Anschlag K, Broll G
  (See online at https://doi.org/10.1657/AAAR0015-073)
• (2017) Upscaling the spatial distribution of enchytraeids and humus forms in a high mountain environment on the basis of GIS and fuzzy logic. European Journal of Soil Biology 79: 1-13
  Hellwig N, Graefe U, Tatti D, Sartori G, Anschlag K, Beylich A, Gobat J-M, Broll G
  (See online at https://doi.org/10.1016/j.ejsobi.2017.01.001)