2014
DOI: 10.5194/hess-18-3623-2014
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Evaluating digital terrain indices for soil wetness mapping – a Swedish case study

Abstract: Abstract. Trafficking wet soils within and near stream and lake buffers can cause soil disturbances, i.e. rutting and compaction. This -in turn -can lead to increased surface flow, thereby facilitating the leaking of unwanted substances into downstream environments. Wet soils in mires, near streams and lakes have particularly low bearing capacity and are therefore more susceptible to rutting. It is therefore important to model and map the extent of these areas and associated wetness variations. This can now be… Show more

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Cited by 140 publications
(137 citation statements)
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“…Comparison with other models, as well as our reference data set, indicate that overall patterns of wetland distribution are well-captured within our study area. The TWI input variable was of greatest importance to our T model (Figure 3), reflecting the importance of local topographic and hydrographic conditions in wetland occurrence: a relationship also demonstrated by other topographically-based wet areas mapping efforts such as those described by [82,83]. Indeed, the TWI showed the greatest influence of all input variables in each of the four probability models, regardless of what additional input variables were included (Figure 3).…”
Section: Modeling Wetland Occurrencementioning
confidence: 86%
“…Comparison with other models, as well as our reference data set, indicate that overall patterns of wetland distribution are well-captured within our study area. The TWI input variable was of greatest importance to our T model (Figure 3), reflecting the importance of local topographic and hydrographic conditions in wetland occurrence: a relationship also demonstrated by other topographically-based wet areas mapping efforts such as those described by [82,83]. Indeed, the TWI showed the greatest influence of all input variables in each of the four probability models, regardless of what additional input variables were included (Figure 3).…”
Section: Modeling Wetland Occurrencementioning
confidence: 86%
“…Divergence in the optimal CA for modeling different soil and vegetation characteristics using DTW is indicated by the range of values reported in the literature [19][20][21]24,55]. In this the foothills landscape is dominated by the fine textured glacial till parent material, and the strength of the relationship between SI and DTW differs with different CA for all three species (Figure 2).…”
Section: Discussionmentioning
confidence: 99%
“…In addition, detailed physical and chemical soil properties, as well as soil, vegetation, and drainage type are found to be subject to topographic controls, and DTW with a 4 ha CA effectively estimated these in the Foothills Natural Region of Alberta [19]. In the Swedish boreal landscape DTW has been shown to be a good predictor of soil wetness, and while it was insensitive to the DEM scale, the optimal CA threshold varied by landform (from 1-2 ha on slowly permeable till deposits to 8-16 ha on coarse-textured deposits where water would drain quickly) [20]. The soil moisture regime, drainage class, and depth-to-mottles were strongly related with DTW at a 2 ha catchment area in young aspen-dominated boreal plain forests [21].…”
Section: Introductionmentioning
confidence: 99%
“…The approach focuses on defining wet soils and areas close to lakes, streams, and mires as they are particularity susceptible to soil disturbances (e.g., rutting and compaction) (Ågren et al, 2014;Murphy et al, 2008a). The depth to water estimates were produced following the wet areas mapping approach described by White et al (2012) and includes: (1) creating a continuous routing flow (Hornberger and Boyer, 1995;Jenson and Domingue, 1988) of water over the ALS-derived terrain model, using a combination of depression filling and breaching; (2), predicting the locations of streams on the surface based on a flow accumulation threshold; (3) interpolating the water table between surface features and calculating the cartographic depth to water.…”
Section: Depth To Watermentioning
confidence: 99%