Greater abundance of Fagus sylvatica in coniferous flood protection forests due to climate change: impact of modified root densities on infiltration

Lange, Benjamin; Germann, Peter; Lüscher, Peter

doi:10.1007/s10342-012-0664-z

Cited by 16 publications

(25 citation statements)

References 38 publications

(37 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…() found root length densities between 0.44 and 2.21 cm/cm 3 in the topsoil of a mixed Norway spruce‐Silver fir forest stand, which corresponds to the values we obtained for the 4‐month and 8‐month old alders. In our study most of the alder roots were smaller than 2 mm in diameter, confirming the importance of the role of fine roots and mesopores (0.5–2 mm in diameter; Sidle et al ., ; Lange et al ., ) and even of root hairs (Bengough, ) in preferential flow paths and saturated flow.…”

Section: Discussionmentioning

confidence: 97%

Soil permeability, aggregate stability and root growth: a pot experiment from a soil bioengineering perspective

2015

View full text Add to dashboard Cite

Assessing the joint development of vegetation cover and soil properties is crucial to evaluate the efficiency of soil bioengineering techniques, especially during the most critical initial phase of vegetation colonization. We set up a laboratory experiment to quantify and disentangle the effect of Alnus incana roots on soil permeability and aggregate stability. Plants were grown in pots in a climate chamber for four different growing periods (1, 2, 4 and 8 months). Pots were filled with a soil coming from a moraine of a landslide area in Central Switzerland. After each growing period, surface permeability, soil volume permeability and soil aggregate stability were measured together with the development of the root systems. Our results show that alder roots significantly improve both surface and whole soil volume permeability already after 2 months of growth. Nevertheless, an increase in root length density does not necessarily correspond to an increase in permeability. We could set as a threshold a root length density of 0.1 cm/cm 3 until which an increase in root development corresponds to an increase in soil permeability, whereas after this threshold we observed a decrease in soil permeability. A significant increase in soil aggregate stability could be observed only with a root length density of 2 cm/cm 3 . No obvious correlation between soil permeability and aggregate stability could be found. Future work should validate these laboratory results with field data.

show abstract

Section: Discussionmentioning

confidence: 97%

Soil permeability, aggregate stability and root growth: a pot experiment from a soil bioengineering perspective

2015

View full text Add to dashboard Cite

show abstract

“…The spatial distributions of roots is linked to the distribution of unit area of momentum dissipation per unit volume L through empirical relationships. The results of previous studies suggest a plausible relation between these two parameters (Lange et al, 2012). The estimated spatial distribution of L implemented in the W 2 model quantifies the hydrological connectivity of vegetated hillslopes of various forest structures and soil conditions ( Fig.…”

mentioning

confidence: 76%

“…Previous studies (Lange et al, 2012) have shown that vertical preferential flow in rooted soils can be quantified at the soil profile scale using a dual porosity models (Šimůnek et al, 2003). In this work we combine the Stokes flow approach (Beven and Germann, 2013) for vertical and lateral fluxes, and the mass balance equation in order to couple information about root distribution, variation of soil water content, and runoff behaviors.…”

Section: Preferential Flow Modeling At the Soil Profile Scalementioning

confidence: 99%

“…The "long" sprinkling experiments aimed to characterize the influence of root distribution on the water content variation within single FDR probes at different soil depth. Previous studies (Lange et al, 2012) used the same type of experiments in order to quantify the influence of root distribution on the infiltration of water analyzing the migration of the wetting fronts between FDR probes at different depths. In these experiments each profiles is irrigated three times at 23 h interval with an intensity of 70 mm/h and a duration of 1 h. These experiments are numerate from P1 to P18.…”

Section: "Long" Sprinkling Experimentsmentioning

confidence: 99%

See 1 more Smart Citation

Subsurface hydrological connectivity of vegetated slopes: a new modeling approach

Schwarz

Giadrossich

Lüscher

et al. 2018

Preprint

Self Cite

View full text Add to dashboard Cite

Abstract. Vegetation strongly influences the hydrology of hillslopes through different processes that may be important for the mitigation of flood risks. The complicated interactions of mechanisms that contribute to the formation of runoff at different spatial and temporal scales represent a big challenge for catchment hydrology. However, it is recognized that storage capacity and infiltration are one of the most important processes positively influenced by vegetation. Moreover, numerical studies have discussed the importance of preferential subsurface flow as dominant processes contributing to fast runoff in mountain catchments. While, previous studies have shown the importance of bedrock topography on the connectivity and drainage of shallow soil mantled hillslopes, no studies discussed the role of heterogeneous root distribution on the drainage of hillslope with stagnic soils so far. In this work we present a conceptual model that aims to link modelling approaches of root distribution combined to hydrological modelling of preferential flow, and the quantification of hydrological connectivity of forest hillslopes. We use a spatial distributed root distribution model to calculate the number of fine roots based on the structure of forest cover (tree position and dimension). The results of root distribution are used as input parameter for the quantification of preferential flow patches using a numerical approach. Finally, we use the spatial distributed values of preferential flow to calculate the hydrological connectivity of a vegetated hillslope considering topography and soil profile characteristics. The new proposed framework is calibrated through field experiments at the soil profile scale, and the first results of the numerical simulations considering different combination of parameters are discussed in the context of protection forests mitigation effects against flood risks.

show abstract

“…according to many authors, natural forests with complexity and integrity are able to withstand various stresses (Dhôte, 1994;Holling, 2001;smith, 2001;Bréda et al, 2006;Weber et al, 2007;Galiano et al, 2010;lloret et al, 2011Cheaib et al, 2012;lange et al, 2012;Michelot et al, 2012;Cavin et al, 2013;vilá-Cabrera, 2013;Morán-lopéz et al, 2014;lawson et al, 2015;Merlin et al, 2015;pötzelsberger et al, 2015) and they are not severely prone to negative functional climate change effects, and therefore, key forest functions can be maintained.…”

Section: Methodsmentioning

confidence: 99%

Succession dynamics of vegetation in the Slovak Karst Biosphere Reserve Landscape (Western Carpathians)

Vološčuk

Uhliarová²,

Sabo

et al. 2016

Ekológia (Bratislava)

View full text Add to dashboard Cite

The paper presents results acquired by an ecological analysis of vegetation succession on the field of the Slovak Karst in south-east Slovakia over the past 25 years. The data were collected on permanent research plots etsablished in 1983−1985 on the Plešivská Plateau (part of the Slovak Karst National Park and Biosphere Reserve). Changes in mesic and dry grassland vegetation of permanent field plots were evaluated in the same way both times according to the Central European method. Due to cessation of non-forest vegetationmanagement the majority, permanent plots isgradually overgrownby woody plants. Succession of vegetation runs faster on karst plateaux where the trees and shrubs invasion is accompanied by overgrowing of grassland vegetation with Brachypodium pinnatum and Calamagrostis epigejos, which are completly change their species composition. On the steep limestone slopes and karst rocky fields of the lower altitudes the secondary succession is ongoing slower and is subjected mainly to accumulation of soil. Succession of herb layer is firstly reflected in changes of species abundance and later in exchanges of dominant species and plant communities. It was also evaluated succession in two forest habitats. In the community Fagetum typicum was evaluated succession after the artificial spruce wind calamity.

show abstract

Greater abundance of Fagus sylvatica in coniferous flood protection forests due to climate change: impact of modified root densities on infiltration

Cited by 16 publications

References 38 publications

Soil permeability, aggregate stability and root growth: a pot experiment from a soil bioengineering perspective

Soil permeability, aggregate stability and root growth: a pot experiment from a soil bioengineering perspective

Subsurface hydrological connectivity of vegetated slopes: a new modeling approach

Succession dynamics of vegetation in the Slovak Karst Biosphere Reserve Landscape (Western Carpathians)

Contact Info

Product

Resources

About