Recent studies of banded vegetation have suggested a successional model, in
which bare bands are colonised in a pioneer front on the upslope side of a
vegetation band. Vegetation patterns in south-west Niger have been interpr
eted to suggest that spatial transitions reflect this form of temporal succ
ession, and in these patterns there is corroborating evidence for slow up-s
lope migration. However, given the inherent difficulties of long-term field
experiments there are few data to judge the validity of this model. The us
e of the artificial radionuclide caesium-137 (Cs-137) to provide informatio
n on net soil flux over the past ca, 30 years offers potential in this rega
rd. Furthermore, the identification of various types of soil crust, which c
an induce different types of hydrological behaviour, provides valuable info
rmation for predicting soil evolution. To test the hypothesis that banded v
egetation migrates upslope, a 70-m transect encompassing two vegetation ban
ds and a single bare lane was sampled in south-west Niger. The transect was
aligned orthogonal to the bands and approximately parallel to the directio
n of water, soil and nutrient flow. Soil samples for gamma-ray spectrometry
and particle-size analysis were collected along the transect at 21 locatio
ns with 1-m intervals in the lower part and three samples were obtained on
the upper part. Prior to collection, the soil surface characteristics were
examined to distinguish between crust types and to identify the presence of
termite activity. The results demonstrate the utility of these techniques
for examining the net redistribution of soil over a period of three decades
and its relations to vegetation succession. The amount of soil eroded was
found generally to decrease downslope, whilst the proportion of fine silt i
n the soil generally increased downslope. These patterns correspond with th
e location of the erosion and sedimentation crusts identified using a stand
ardised classification. The relations between microtopography and net soil
flux may also explain some of the spatial variation in soil redistribution
processes. The intensity of crust and Cs-137 measurements on the upslope ed
ge of the lower vegetation band enabled the calculation of the upslope migr
ation rate (ca. 0.19-0.27 m yr(-1)) which coincided with independent studie
s in the same region. However, because considerable spatial variations in t
opography and soil flux were found to occur over very small distances, furt
her detailed studies over larger areas will be needed. (C) 1999 Elsevier Sc
ience B.V. All rights reserved.