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Spatial variation of earthworm communities and soil organic carbon in temperate agroforestry

  • Rémi Cardinael
  • Kevin Hoeffner
  • Claire Chenu
  • Tiphaine Chevallier
  • Camille Béral
  • Antoine Dewisme
  • Daniel Cluzeau
Original Paper

Abstract

The aim of this study was to assess how soil organic C (SOC) stocks and earthworm communities were modified in agroforestry systems compared to treeless control plots and within the agroforestry plots (tree rows vs alleys). We used a network of 13 silvoarable agroforestry sites in France along a north/south gradient. Total earthworm abundance and biomass were significantly higher in the tree rows than those in the control plots, but were not modified in the alleys compared to those in the control plots. Earthworm species richness, Shannon index, and species evenness were significantly higher in the tree rows than those in the alleys. Total abundance of epigeic, epi-anecic, strict anecic, and endogeic was higher in the tree rows. Surprisingly, earthworm individual weight was significantly lower in the tree rows than that in the alleys and in the control plots. SOC stocks were significantly higher in the tree rows compared to that in the control plots across all sites. Despite higher SOC stocks in the tree rows, the amount of available C per earthworm individual was lower compared to those in the control. The absence of disturbance (no tillage, no fertilizers, no pesticides) in the tree rows rather than increased SOC stocks therefore seems to be the main factor explaining the increased total abundance, biomass, and diversity of earthworms. The observed differences in earthworm communities between tree rows and alleys may lead to modified and spatially structured SOC dynamics within agroforestry plots.

Keywords

Silvoarable system Alley cropping Earthworm abundance Earthworm diversity Lumbricidae 

Notes

Acknowledgments

We thank Hoël Hotte and Morgane Ollivier for their technical assistance during the earthworm field sampling.

Funding information

This study was financed by the French Environment and Energy Management Agency (ADEME), following a call for proposals as part of the REACCTIF program (Research on Climate Change Mitigation in Agriculture and Forestry). This study was part of the funded project AGRIPSOL (Agroforestry for Soil Protection), coordinated by AGROOF. Rémi Cardinael’s PhD thesis was co-funded by La Fondation de France and ADEME. Kevin Hoeffner’s PhD thesis was funded by a grant of the French Ministry of Research.

Supplementary material

374_2018_1332_MOESM1_ESM.docx (1.7 mb)
ESM 1 (DOCX 1692 kb)

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Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2018

Authors and Affiliations

  1. 1.Eco&Sols, IRD, CIRAD, INRA, Montpellier SupAgroUniversity of MontpellierMontpellierFrance
  2. 2.UMR Ecosys, INRA, AgroParisTechUniversité Paris SaclayThiverval-GrignonFrance
  3. 3.CIRAD, UPR AIDAMontpellierFrance
  4. 4.AIDA, CIRADUniversity of MontpellierMontpellierFrance
  5. 5.CNRS, ECOBIO UMR 6553University of RennesRennesFrance
  6. 6.AGROOFAnduzeFrance

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