Cardinael Rémi, Chevallier Tiphaine, Germon Amandine, Jourdan Christophe, Dupraz Christian, Barthès Bernard, Bernoux Martial, Chenu Claire.
2015. Agroforestry for a climate-smart agriculture – a case study in France. [P95].
In : Building tomorrow’s research agenda and bridging the science-policy gap. CIRAD, INRA, IRD, Agropolis International, Wageningen UR, CGIAR, UCDAVIS, FAO, Agreenium, GFAR
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Version publiée
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Utilisation soumise à autorisation de l'auteur ou du Cirad. P95 de L1 Regional Dimensions(1)-9.pdf Télécharger (365kB) | Prévisualisation |
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Version publiée
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Utilisation soumise à autorisation de l'auteur ou du Cirad. ID576574_p.pdf Télécharger (5MB) | Prévisualisation |
Matériel d'accompagnement : 1 poster
Résumé : Agroforestry is a land use type where crops and trees are grown together in the same place and at the same time. Agroforestry systems have the advantage of providing multiple products (e.g. wood, fruits) or services (e.g. biodiversity enhancement, erosion control) whilst maintaining agricultural production. If they are known to store carbon into the biomass of the trees, they could also increase soil organic carbon (SOC) stocks. However their impact has rarely been studied under temperate conditions and has mostly concerned superficial soil layers. Our objectives were (i) to quantify and spatialize SOC stocks in an agroforestry system and in an adjacent agricultural plot, (ii) to assess what SOC fractions are responsible for possible additional carbon storage, and (iii) to quantify all organic inputs entering the soil. The trial was established in 1995 in southern France. Hybrid walnut trees are intercropped with durum wheat. SOC stocks were measured on 200 soil cores down to 2 m soil depth, and particle-size fractionation was performed on 64 soil samples. Carbon stocks of trees and of the herbaceous vegetation in the tree rows were also quantified. A trench was dug to 4 m soil depth to quantify tree fine root distribution and biomass. Minirhizotrons were installed at different depths to study tree fine root turnover. Annual additional SOC storage rates were estimated at 259 ± 59 kg C ha-1 yr-1 (0-30 cm) and at 350 ± 88 kg C ha-1 yr-1 (0-100 cm), and were mainly due to particulate organic matter fractions (> 50 μm). Only 10 to 15% was associated to clay particles. When the biomass of the trees was taken into account, total organic carbon storage rate reached 1.2 Mg C ha-1 yr-1. High tree root densities were observed at depth, but root turnover decreased with depth. Agroforestry systems provide higher amounts of carbon at depth than other agricultural practices, like no-till farming, and could therefore provide a more stable C storage in the long-term.
Classification Agris : F08 - Systèmes et modes de culture
K10 - Production forestière
P33 - Chimie et physique du sol
P01 - Conservation de la nature et ressources foncières
Auteurs et affiliations
- Cardinael Rémi, IRD (FRA) ORCID: 0000-0002-9924-3269
- Chevallier Tiphaine, IRD (FRA)
- Germon Amandine, INRA (FRA)
- Jourdan Christophe, CIRAD-PERSYST-UMR Eco&Sols (FRA) ORCID: 0000-0001-9857-3269
- Dupraz Christian, INRA (FRA)
- Barthès Bernard, IRD (FRA)
- Bernoux Martial, IRD (FRA)
- Chenu Claire, AgroParisTech (FRA)
Source : Cirad-Agritrop (https://agritrop.cirad.fr/576574/)
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