Millimetre scale aeration of the rhizosphere and drilosphere

Uteau, Daniel ORCIDiD
Horn, Rainer
Peth, Stephan ORCIDiD

DOI: https://doi.org/10.1111/ejss.13269
Persistent URL: http://resolver.sub.uni-goettingen.de/purl?gldocs-11858/10235
Uteau, Daniel; Horn, Rainer; Peth, Stephan, 2022: Millimetre scale aeration of the rhizosphere and drilosphere. In: European Journal of Soil Science, 73, 4, DOI: https://doi.org/10.1111/ejss.13269. 
 
Horn, Rainer; 2 Institute of Plant Nutrition and Soil Science University of Kiel Kiel Germany
Peth, Stephan; 3 Institute of Soil Science, Faculty of Natural Sciences Leibniz University Hannover Hannover Germany

Abstract

Soil aeration is a critical factor for oxygen‐limited subsoil processes, as transport by diffusion and advection is restricted by the long distance to the free atmosphere. Oxygen transport into the soil matrix is highly dependent on its connectivity to larger pore channels like earthworm and root colonised biopores. Here we hypothesize that the soil matrix around biopores represents different connectivity depending on biopore genesis and actual coloniser. We analysed the soil pore system of undisturbed soil core samples around biopores generated or colonised by roots and earthworms and compared them with the pore system of soil, not in the immediacy of a biopore. Oxygen partial pressure profiles and gas relative diffusion was measured in the rhizosphere and drilosphere from the biopore wall into the bulk soil with microelectrodes. The measurements were linked with structural features such as porosity and connectivity obtained from X‐ray tomography and image analysis. Aeration was enhanced in the soil matrix surrounding biopores in comparison to the bulk soil, shown by higher oxygen concentrations and higher relative diffusion coefficients. Biopores colonised by roots presented more connected lateral pores than earthworm colonised ones, which resulted in enhanced aeration of the rhizosphere compared to the drilosphere. This has influenced biotic processes (microbial turnover/mineralization or root respiration) at biopore interfaces and highlights the importance of microstructural features for soil processes and their dependency on the biopore's coloniser.