The AMMA-CATCH experiment in the cultivated Sahelian area of south-west Niger – Investigating water cycle response to a fluctuating climate and changing environment

Cappelaere, Bernard; Descroix, Luc; Lebel, Thierry; Boulain, N.; Ramier, David; Laurent, Jean‐Paul; Favreau, Guillaume; Boubkraoui, Stéphane; Boucher, Marie; Moussa, I. Bouzou; Chaffard, Véronique; Hiernaux, Pierre; Issoufou, Hassane Bil-Assanou; Breton, Éric Le; Mamadou, Ibrahim; Nazoumou, Yahaya; Oï, Monique; Ottlé, Catherine; Quantin, Guillaume

doi:10.1016/j.jhydrol.2009.06.021

Cited by 118 publications

(78 citation statements)

References 64 publications

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“…In the framework of the AMMA project, meso-scale sites have been instrumented in Mali, Niger and Benin, providing ground data along the latitudinal gradient between Sahelian and Sudanian bioclimatic regions Cappelaere et al, 2009;Mougin et al, 2009a;de Rosnay et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Mapping surface soil moisture over the Gourma mesoscale site (Mali) by using ENVISAT ASAR data

Baup

Mougin

Rosnay

et al. 2011

Hydrol. Earth Syst. Sci.

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Abstract. The potentialities of ENVISAT ASAR (Advanced Synthetic Aperture Radar) multi-angle data for mapping surface soil moisture (SSM) in Sahelian rangelands are investigated at medium scale (30 000 km 2 ). The Wide Swath data are selected to take advantage of their high temporal repetitivity (about 8 days at the considered scale) associated to a moderate spatial resolution (150 m). In the continuity of previous studies conducted at a local scale in the same region, SSM maps are here processed over the whole AMMA Gourma mesoscale site at 1 km resolution scale. Overall, the generated maps are found to be in good agreement with field data, EPSAT-SG (Estimation des Pluies par SATellite -Second Generation) rainfall estimates and ERS (European Remote Sensing) Wind Scatterometer (WSC) SSM products. The present study shows that the spatial pattern of SSM can be realistically estimated at a kilometric scale. The resulting SSM maps are expected to provide valuable information for initialisation of land surface models and the estimation of the spatial distribution of radiative fluxes. Particularly, SSM maps could help to desaggregate low-resolution products such as those derived from WSC data.

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Section: Introductionmentioning

confidence: 99%

Mapping surface soil moisture over the Gourma mesoscale site (Mali) by using ENVISAT ASAR data

Baup

Mougin

Rosnay

et al. 2011

Hydrol. Earth Syst. Sci.

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“…This continuous series was obtained by combining a unique field data set over that period Cappelaere et al, 2009;Ramier et al, 2009) with the physically based SiSPAT (Simple Soil-Plant-Atmosphere Transfers) model (Braud et al, 1995). The study area is located in the so-called central Sahel region, which is considered the most representative of the West African monsoon rainfall regime (Lebel and Ali, 2009).…”

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confidence: 99%

Building a field- and model-based climatology of local water and energy cycles in the cultivated Sahel – annual budgets and seasonality

Velluet

Demarty

Cappelaere

et al. 2014

Hydrol. Earth Syst. Sci.

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Abstract. In the sub-Saharan Sahel, energy and water cycling at the land surface is pivotal for the regional climate, water resources and land productivity, yet it is still very poorly documented. As a step towards a comprehensive climatological description of surface fluxes in this area, this study provides estimates of long-term average annual budgets and seasonal cycles for two main land use types of the cultivated Sahelian belt: rainfed millet crop and fallow bush. These estimates build on the combination of a 7-year field data set from two typical plots in southwestern Niger with detailed physically based soil-plant-atmosphere modeling, yielding a continuous, comprehensive set of water and energy flux and storage variables over this multiyear period. In the present case in particular, blending field data with mechanistic modeling makes the best use of available data and knowledge for the construction of the multivariate time series. Rather than using the model only to gap-fill observations into a composite series, model-data integration is generalized homogeneously over time by generating the whole series with the entire data-constrained model simulation. Climatological averages of all water and energy variables, with associated sampling uncertainty, are derived at annual to subseasonal scales from the time series produced. Similarities and differences in the two ecosystem behaviors are highlighted. Mean annual evapotranspiration is found to represent ∼ 82-85 % of rainfall for both systems, but with different soil evaporation/plant transpiration partitioning and different seasonal distribution. The remainder consists entirely of runoff for the fallow, whereas drainage and runoff stand in a 40-60 % proportion for the millet field. These results should provide a robust reference for the surface energy-and water-related studies needed in this region. Their significance and the benefits they gain from the innovative data-model integration approach are thoroughly discussed. The model developed in this context has the potential for reliable simulations outside the reported conditions, including changing climate and land cover.Published by Copernicus Publications on behalf of the European Geosciences Union.

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“…The most likely explanation for the more strongly increasing AMAX compared to precipitation is therefore a stronger effect of land-use change compared to other regions [23]. This effect was found by several detailed studies on effects of land-use changes for the Sahel region [3,[69][70][71]. However, the role of the groundwater in the region is also very complex and should be addressed systematically in order to see how it influences high flows [72,73].…”

Section: Discussionmentioning

confidence: 93%

Time Series Analysis of Floods across the Niger River Basin

Aich

Koné²,

Hattermann

et al. 2016

Water

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Abstract:This study analyses the increasing number of catastrophic floods in the Niger River Basin, focusing on the relation between long term hydro-climatic variability and flood risk over the last 40 to 100 years. Time series for three subregions (Guinean, Sahelian, Benue) show a general consistency between the annual maximum discharge (AMAX) and climatic decadal patterns in West Africa regarding both trends and major changepoints. Variance analysis reveals rather stable AMAX distributions except for the Sahelian region, implying that the changes in flood behavior differ within the basin and affect mostly the dry Sahelian region. The timing of the floods within the year has changed only downstream of the Inner Niger Delta due to retention processes. The results of the hydro-climatic analysis generally correspond to the presented damage statistics on people affected by catastrophic floods. The damage statistics shows positive trends for the entire basin since the beginning in the 1980s, with the most extreme increase in the Middle Niger.

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The AMMA-CATCH experiment in the cultivated Sahelian area of south-west Niger – Investigating water cycle response to a fluctuating climate and changing environment

Cited by 118 publications

References 64 publications

Mapping surface soil moisture over the Gourma mesoscale site (Mali) by using ENVISAT ASAR data

Mapping surface soil moisture over the Gourma mesoscale site (Mali) by using ENVISAT ASAR data

Building a field- and model-based climatology of local water and energy cycles in the cultivated Sahel – annual budgets and seasonality

Time Series Analysis of Floods across the Niger River Basin

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