Larsbo, Mats
- Department of Soil and Environment, Swedish University of Agricultural Sciences
Research article2016Peer reviewedOpen access
Larsbo, Mats; Koestel, Johannes; Kätterer, Thomas; Jarvis, Nicholas
It has been suggested that some management practices and farming systems that promote C sequestration may exacerbate the risk of groundwater pollution due to fast preferential transport in soil macropores. However, soil organic C (SOC) may also impact the soil pore structure at scales smaller than the macropore scale, where complexes of SOC and clay form micro-aggregates that may increase pore volumes in the micrometer size range. These effects of SOC per se on pore network architecture, water flow, and solute transport have hardly been investigated. Therefore, to investigate this question, we measured tracer transport through soil cores sampled along a transect on a field under grass-clover ley with a natural gradient in SOC content. The strength of preferential transport was characterized at two flow rates (2 and 5 mm h-1) and related to the volume, size distribution, heterogeneity, and connectivity of pore networks quantified by X-ray tomography. The results showed that soils with a larger SOC content had larger volumes of pores in the smallest imaged size range (200-600 mm) that were also more uniformly distributed. These effects of SOC on the imaged pore networks were only apparent up to a threshold value of the ratio between clay and SOC of 10: 1, which is assumed to correspond with the amount of SOC needed for C saturation of the clay fraction. The increased flow capacity of these smaller macropores in soil columns with larger SOC contents prevented flow from being activated in larger pores, which significantly reduced the strength of preferential transport.
Vadose Zone Journal
2016, Volume: 15, number: 9Publisher: SOIL SCI SOC AMER
SDG2 Zero hunger
Environmental Sciences
Soil Science
DOI: https://doi.org/10.2136/vzj2016.03.0021
https://res.slu.se/id/publ/80552