Abstract
Animal activity and litter quality play a key role in forests on decalcified Steinmergelkeuper marls. The dominant trees hornbeam and beech clearly differ in litter quality, which affects earthworm activity and soil formation. Trees were even more important to topsoil characteristics than the subsoil. Under hornbeam, with high-palatable litter, organic layers were thinner, species richness higher and topsoils wetter and less acidic than under beech with more recalcitrant litter. In decalcified marl, lateral clay eluviation leads to differentiation in silty topsoils and clay-rich, water-impermeable Bg-horizons. Depth of the impermeable layer was shallower under hornbeam than under beech. Under hornbeam, formation of silty topsoils is probably counteracted by erosion. High animal activity leads to increased denudation of the surface, macropore systems with pipe flow in the soil, and approximately ten times higher export of soil particles than under beech. Under the low-palatable beech, leaching can continue without interruption, due to protective litter covers, low macroporosity, and throughflow with loss of base cations and clay particles rather than silt and sand. The two trees also showed habitat preferences, which extend their presence in particular habitats beyond the lifespan of individual trees. Hornbeam seedlings were only found under hornbeam, and are probably better adapted to wetness with superficial fine roots. Beech seedlings established everywhere, but further growth may be hampered in wet places due to three-dimensional fine root systems. Hornbeam and beech thus act as ecosystem engineers, with different litter quality and animal activity leading to more suitable habitat conditions for themselves, and development of wet and dry subsystems in the forest.
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Aubert M, Hedde M, Decaens T, Bureau F, Margerie P, Alard D (2003) Effects of tree canopy composition on earthworms and other macro-invertebrates in beech forests of Upper Normandy (France). Pedobiologia 47:904–912
Aubert M, Bureau F, Alard D, Bardat J (2004) Effect of tree mixture on the humic epipedon and vegetation diversity in managed beech forests (Normandy, France). Can J For Res 34:233–248
Beatty SW, Sholes ODV (1988) Leaf litter effects on plant species composition of deciduous forest treefall pits. Can J For Res 18:553–559
Berg B (2000) Litter decomposition and organic matter turnover in northern forest soils. For Ecol Manage 133:13–22
Bijlsma RJ, Lambers H, Kooijman SALM (2000) A dynamic whole-plant model of integrated metabolism of nitrogen and carbon. 1. Comparative ecological implications of ammonium-nitrate interactions. Plant Soil 220:49–69
Bolte A, Czajkowski T, Kompa T (2007) The north-eastern distribution range of European beech—a review. Forestry 80:413–429
Brunet J, Falkengren-Grerup U, Tyler G (1997) Pattern and dynamics of the ground vegetation in south Swedish Carpinus betulus forests: importance of soil chemistry and management. Ecography 20:513–520
Cammeraat LH (1992) Hydro-geomorphological processes in a small forested sub-catchment: preferred flow-paths of water. Ph.D. thesis University of Amsterdam, 158 p
Cammeraat LH (2002) A review of two strongly contrasting geomorphological systems within the context of scale. Earth Surf Proc Land 27:1201–1222
Cammeraat LH, Kooijman AM (2009) Biological control of pedological and hydro-geomorphological processes in a deciduous forest ecosystem. Biologia 64:428–432
Cody RP, Smith JK (1987) Applied Statistics and the SAS Programming Language. Elsevier Science Publishers Co. Int., New York
Davidson DA, Bruneau PMC, Grieve IC, Wilson CA (2004) Micromorphological assessment of the effect of liming on faunal excrement in an upland grassland soil. Appl Soil Ecol 26:169–177
Diekmann M, Falkengren-Grerup U (2003) A new species index for forest vascular plants: development of functional indices based on mineralization rates of various forms of soil nitrogen. J Ecol 86:269–283
Duijsings JJHM (1985) Streambank contribution to the sediment budget of a forest stream. Ph.D. thesis University of Amsterdam, 190 p
Duijsings JJHM (1987) A sediment budget for a forested catchment in Luxembourg and its implications for channel development. Earth Surf Proc Land 12:173–184
Duchaufour P (1982) Pedology; pedogenesis and classification (trans: Paton TR). George Allen & Unwin, London. 448 p
Duvigneaud P, Denayer-De Smet S (1970) Biological cycling of minerals in temperate deciduous forests. In: Reichle DE (ed) Analysis of temperate forest ecosystems. Springer, Berlin, pp 199–225
Edwards CA, Lofty JR (1977) Biology of earthworms. Chapman and Hall, London
Ellenberg H, Weeber HE, Düll R, Wirth V, Werner W (1974) Zeigerwerte von Pflanzen in Mitteleuropa. Verlag Erich Goltze GmbH & Co, Gottingen
Falkengren-Grerup U (1995) Interspecies differences in the preference of ammonium and nitrate in vascular plants. Oecologia 102:305–311
Ferraris le Comte de (1777) Reissued in 1965–1970. Carte de Cabinet des Pays-Bas Autrichiens. Bibiliotheque Royale de Belgique, Bruxelles
Green RN, Trowbridge RL, Klinka K (1993) Towards a taxonomic classification of humus forms. Suppl Forest Sci 39
Greene RSB, Hairsine PB (2004) Elementary processes of soil–water interaction and thresholds in soil surface dynamics: a review. Earth Surf Proc Land 29:1077–1091
Hane EN, Hamburg SP, Barber AL, Plaut JA (2003) Phytotoxicity of American beech leaf leachate to sugar maple seedlings in a greenhouse experiment. Can J For Res 33:814–821
Hazelhoff H, van Hooff P, Imeson AC, Kwaad FJPM (1981) The exposure of forest soil to erosion by earthworms. Earth Surf Proc Land 6:235–250
Hendriks MR, Imeson AC (1984) Non-channel storm period sediment supply from a topographical depression under forest in the Keuper region of Luxembourg. Zeitschrift für Geomorfologie N.F.Suppl.-Bd 49:51–58
Hornung M (1985) Acidification of soils by trees and forests. Soil Use Manage 1:24–28
Imeson AC, Vis M (1984) The output of sediments and solutes from forested and cultivated clayey drainage basins in Luxembourg. Earth Surf Proc Land 9:585–594
Imeson AC (1986) Investigating volumetric changes in clayey soils related to subsurface water movement and piping. Zeitschrift für Geomorfologie N.F.Suppl.-Bd 60:115–130
IUSS Working Group WRB (2015) World reference base for soil resources 2014, update 2015. International soil classification system for naming soils and creating legends for soil maps. World Soil Resources Reports No. 106. FAO, Rome
Jongmans AG, Pulleman MM, Balabane M, van Oort F, Marinissen JCY (2003) Soil structure and characteristics of organic matter in two orchards differing in earthworm activity. Appl Soil Ecol 24:219–232
Jungerius PD, van Zon HJM (1982) The formation of the Lias cuesta (Luxembourg) in the light of present day erosion processes operating on forest soils. Geogr Ann 64A:127–140
Jungerius PD, van de Ancker H, van Zon HJM (1989) Long term measurement of forest soil exposure and creep in Luxembourg. Catena 16:437–447
Kooijman AM, Martinez-Hernandez GB (2009) Effects of litter quality and parent material on organic matter characteristics and N-dynamics in Luxembourg beech and hornbeam forests. For Ecol Manage 257:1732–1739
Kooijman AM, Cammeraat LH (2010) Biological control of beech and hornbeam on species richness via changes in the organic layer, pH and soil moisture characteristics. Funct Ecol 24:469–477
Laskowski R, Niklinska M, Maryanski M (1995) The dynamics of chemical elements in forest litter. Ecology 76:1393–1406
Lee KE, Foster RC (1991) Soil fauna and soil structure. Aust J Soil Res 29:745–775
Mohr R, Topp W (2005) Hazel improves soil quality of sloping oak stands in German low mountain range. Ann For Sci 62:23–29
Niemeyer T, Ries C, Härdtle W (2010) Die Waldgesellschaften Luxemburgs. Vegetation, Standort, Vorkommen und Gefährdung. Ferrantia 57, Musée national d’histoire naturelle, Luxembourg, 122 p
Neirynck J, Mirtcheva S, Sioen G, Lust N (2000) Impact of Tilia platyphyllos Scop., Fraxinus excelsior L., Acer pseudoplatanus L., Quercus robur L., and Fagus sylvatica L. on earthworm biomass and physico-chemical properties of a loamy topsoil. For Ecol Manage 133:275–286
Oades JM (1993) The role of biology in the formation, stabilization and degradation of soil structure. Geoderma 56:377–400
van Oijen D, Feijen M, Hommel P, den Ouden J, de Waal R (2005) Effects of tree species composition on within-forest distribution of understorey species. Appl Veg Sci 8:155–166
Olson JS (1963) Energy storage and the balance of producers and decomposers in ecological systems. Ecology 44:322–331
Pärtel M (2002) Local plant diversity patterns and evolutionary history at the regional scale. Ecology 83:2361–2366
Ponge JF (2003) Humus forms in terrestrial ecosystems: a framework to biodiversity. Soil Biol Biochem 35:935–945
Pop V (1997) Earthworm-vegetation-soil relationships in the Romanian Carpathians. Soil Biol Biochem 29:223–229
Pulleman MM, Six J, van Breemen N, Jongmans AG (2005) Soil organic matter distribution and microaggregate characteristics as affected by agricultural management and earthworm activity. Eur J Soil Sci 56:453–467
Schachtschabel F, Blume H, Hartge KH, Schwertmann U, Brümmer GW, Renger M (1982) Scheffer/Schachtschabel Lehrbuch der Bodenkunde, 11th edn. Enke Verlag, Stuttgart, p 442
Slotboom RT (1963) Comparative geomorphological and palynological investigations of the Pingos (Viviers) in the Hautes Fanges (Belgium) and the Mardellen in the Gutland (Luxembourg). Zeitschrift für Geomorfologie N.F 7:1–41
Swift MJ, Heal OW, Anderson JM (1979) Decomposition in terrestrial ecosystems. University of California Press, Berkeley
Sydes C, Grime JP (1981) Effects of tree litter on herbaceous vegetation in deciduous woodland I. Field investigations. J Ecol 69:237–248
van Hooff P (1983) Earthworm activity as a cause of splash erosion in Luxembourg forests. Geoderma 31:195–204
Vincke C, Celvaux B (2005) Porosity and available water of temporarily waterlogged soils in a Quercus robur (L.) declining stand. Plant Soil 271:189–203
van den Berg LJL, Dorland E, Vergeer P, Hart M, Bobbink R, Roelofs JGM (2005) Decline of acid-sensitive plant species in heathland can be attributed to ammonium toxicity in combination with low pH. New Phytol 166:551–564
van den Broek TMW (1989) Clay dispersion and pedogenesis of soils with an abrupt contrast in texture: a hydro-pedological approach on subcatchment scale. Ph.D. thesis University of Amsterdam, 109 p
Westerman RL (1990) Soil testing and plant analysis, 3rd edn. Soil Science Society America, Madison, Wisconsin
Westernacher E, Graff O (1987) Orientation behaviour of earthworms (Lumbricidae) towards different crops. Biol Fertil Soils 3:131–133
Wolters V, Stickan W (1991) Resource allocation of beech seedlings (Fagus sylvatica L.)—relationship to earthworm activity and soil conditions. Oecologia 88:125–131
Zou C, Sands R, Buchan G, Hudson I (2000) Least limiting water range: a potential indicator of physical quality of forest soils. Aust J Soil Res 38:947–958
Zvereva EL, Toivonen E, Kozlov MV (2007) Changes in species richness of vascular plants under the impact of air pollution: a global perspective. Glob Ecol Biogeogr 17:305–319
van Zon HJM (1980) The transport of leaves and sediment over a forest floor. Catena 7:97–110
Acknowledgements
The authors would like to thank Bas van Dalen, Greet Kooijman-Schouten and Lex Weiler for their help in the field, and Leo Hoitinga for assistance in the laboratory. The photograph and part of the figures were made by Jan van Arkel.
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Kooijman, A.M., Cammeraat, L.H., Cusell, C., Weiler, H., Imeson, A.C. (2018). Soil Animals and Litter Quality as Key Factors to Plant Species Richness, Topsoil Development and Hydrology in Forests on Decalcified Marl. In: Kooijman, A., Cammeraat, L., Seijmonsbergen, A. (eds) The Luxembourg Gutland Landscape. Springer, Cham. https://doi.org/10.1007/978-3-319-65543-7_10
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