Clay mineralogy differs qualitatively in aggregate‐size classes: clay‐mineral‐based evidence for aggregate hierarchy in temperate soils |
| |
| Authors: | O Fernández‐Ugalde P Barré F Hubert I Virto C Girardin E Ferrage L Caner C Chenu |
| |
| Institution: | 1. Laboratoire de Géologie, UMR 8538, CNRS‐ENS, Ecole Normale Supérieure, , 75231 Paris Cedex 5, France;2. IC2MP‐HydrASA, UMR 7285, Université de Poitiers, , 86022 Poitiers, France;3. Departamento Ciencias del Medio Natural, ETSIA, Universidad Pública de Navarra, , 31006 Pamplona, Spain;4. Laboratoire BIOEMCO, AgroParisTech, , 78850 Thiverval‐Grignon, France |
| |
| Abstract: | Clay minerals have a major role in soil aggregation because of their large specific surface area and surface charges, which stimulate interactions with other mineral particles and organic matter. Soils usually contain a mixture of clay minerals with contrasting surface properties. Although these differences should result in different abilities of clay minerals regarding aggregate formation and stabilization, the role of different clay minerals in aggregation has been seldom evaluated. In this study, we took advantage of the intrinsic mineral heterogeneity of a temperate Luvisol to compare the role of clay minerals in aggregation. First, grassland and tilled soil samples were separated in water into aggregate‐size classes based on the aggregate hierarchy model. Then, clay mineralogy and organic C in the aggregate‐size classes were analysed. Interstratified minerals containing swelling phases accumulated in aggregated fractions compared with free clay fractions under the two land‐uses. The accumulation increased with decreasing aggregate size from large macroaggregates (> 500 µm) to microaggregates (50–250 µm). Carbon content and carbon‐to‐nitrogen ratio followed the opposite trend. This fully supports the aggregate hierarchy model, which postulates an increasing importance of mineral reactivity in smaller aggregates than in larger aggregates in which the cohesion relies mostly on physical enmeshment by fungal hyphae or small roots. Consequently, differences in the proportion of the different 2:1 clay minerals in soils can influence their structure development. Further research on the links between clay mineralogy and aggregation can improve our understanding of mechanisms of soil resistance to erosion and organic matter stabilization. |
| |
| Keywords: | |
|
|
