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Adaptative above-ground biomass, stand density and leaf water potential to droughts and clearing in Guiera senegalensis, a dominant shrub in Sahelian fallows (Niger)

Published online by Cambridge University Press:  16 February 2005

Josiane Seghieri
Affiliation:
ORSTOM, BP. 11416 – Niamey, Niger
Monique Simier
Affiliation:
IRD (ex-ORSTOM)- Centre de Recherche Halieutique Méditerranéenne et Tropicale, avenue Jean Monnet - B.P. 171, 34203 Sète Cedex, France
Ali Mahamane
Affiliation:
University Abdou Moumouni, département de Biologie, faculté des Sciences, BP 10662 Niamey, Niger
Pierre Hiernaux
Affiliation:
Tropenzentrum (Centre for Agriculture in the Tropics and Subtropics), Universität Hohenheim (790) 70593 Stuttgart, Germany
Serge Rambal
Affiliation:
CEFE-CNRS L. Emberger, 1919 route de Mende, BP. 5051, 34293, Montpellier, Cedex 5, France

Abstract

Guiera senegalensis tolerates repeated cutting and pruning to which it is increasingly subjected at the onset of each cropping period, and one to three times during the annual cropping period (June–September). It responds by profusely branching at the shrub base. The topographic and geomorphic influences, and the effect of clearing on the relationships between shrub density, mean individual above-ground biomass and leaf water status were analysed for seven fallow sites. They were sampled 75 km east of Niamey in Niger. Surprisingly, shrub density and mean individual above-ground biomass were highest in the sites that had been recently in fallow and intensively cultivated prior to crop abandonment. Stand above-ground biomass was also positively related to mean predawn and daily minimum leaf water potentials. Consequently, in the studied G. senegalensis stands, above-ground biomass appeared to be controlled by water availability – rainfall, runoff, infiltration – rather than by cropping intensity. Anisohydric stomatal regulation, resulting in large safety margins from critical transpiration, was inferred from the diurnal amplitude of leaf water potential during the dry season. The plant physiological resistance to water stress combined with its population adjustment in density and growth contributes to the sustainable dominance of G. senegalensis.

Type
Research Article
Copyright
2005 Cambridge University Press

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