Olivier Planchon scite author profile

The accuracy of the predictions of distributed hydrological models must depend in part on the proper specification of flow pathways. This paper examines some of the problems of deriving flow pathways from raster digital terrain data in the context of hydrological predictions using TOPMODEL. Distributed moisture status is predicted in TOPMODEL on the basis of spatial indices that depend on flow path definition. The sensitivity of this index to flow path algorithm and grid size is examined for the case where the surface topography is a good indicator of local hydraulic gradients. A strategy for the case where downslope subsurface flow pathways may deviate from those indicated by the surface topography is described with an example application.

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A fast, simple and versatile algorithm to fill the depressions of digital elevation models

Planchon

Darboux

2002

CATENA

373

272

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Preferential erosion of black carbon on steep slopes with slash and burn agriculture

Rumpel

Chaplot²,

Planchon

et al. 2006

CATENA

176

130

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Soil crusting and infiltration on steep slopes in northern Thailand

Janeau¹,

Bricquet²,

Planchon

et al. 2003

European J Soil Science

145

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Summary Predicting the rate at which rain infiltrates on steep slopes is very uncertain. There is no consistent information in the literature. We have therefore related infiltrability to slope gradient under field conditions by experimenting on a gravelly loamy soil occupying the upper half of a cultivated convex hill in northern Thailand. Fifteen 1 m × 1 m plots with slope gradients ranging from 16 to 63% were established, and simulated rain was allowed to fall on them at controlled rates and for fixed times. We obtained the following results. The surface fell 0.4–7.2 mm due to compaction and soil loss. The proportions of crust (0–40%) and embedded gravel (10–60%), the runoff coefficient (0.05–0.78 mm mm−1), the mean sediment concentrations (0–5.6 g l−1), and soil detachment (10–313 g m−2) were more pronounced on the gentle slopes than on the steep ones. The steady final infiltration rate (1–107 mm hour−1) increased sharply with increasing slope gradient. Microaggregates tended to behave like sand and become tightly packed on gentle slopes (packing crust). These results suggest that the vertical component of kinetic energy, which is greater on gentle slopes, has a dominant role. Nevertheless, the differences in compaction and in sediment concentration could not be ascribed to the vertical component of kinetic energy alone. On steep slopes the horizontal component of the kinetic energy is transformed into shear stress, hampering the development of crusts so that water can still infiltrate. On steeper slopes, the water film was thinner, thereby limiting the role of splash. We conclude that the relationship between slope gradient and infiltrability depends on the nature of the soil and must be examined in the light of surface crusting processes.

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Erosion budget and process selectivity of black carbon at meter scale

Rumpel

Darboux

et al. 2009

Geoderma

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