Title: | Subsoil Microbial Processes Under Australian Rotational Cotton Systems |
Contributor(s): | Polain, Katherine (author) ; Knox, Oliver (supervisor) ; Wilson, Brian (supervisor) |
Conferred Date: | 2022-02-03 |
Copyright Date: | 2022 |
Handle Link: | https://hdl.handle.net/1959.11/56661 |
Related Research Outputs: | https://doi.org/10.1071/SR19335 https://doi.org/10.1021/acsearthspacechem.8b00021 https://doi.org/10.3390/soilsystems4030044 https://hdl.handle.net/1959.11/56662 |
Abstract: | | Soil microbiota have been well characterised in agricultural topsoils (0 - 30 cm depth) globally. However, understanding of microbial functioning below 30 cm is in its infancy, particularly in the Southern Hemisphere. Increasing pressure on developing sustainable agricultural practices has instigated a shift to investigating subsoil (>30 cm depth) microbial dynamics. In the Australian cotton industry, interest in subsoils has increased due to the physical properties of Vertosol soils, on which most Australian cotton is grown. Commonly referred to as 'cracking clays', Vertosols have the unique characteristics of self-mulching and cracks extending well below the topsoil. These properties, along with frequent irrigations, are thought to facilitate the movement of organic matter and other nutrients, into deeper soil horizons and hypothesised to be utilised by subsoil microbiota.
This project represents an initial study into microbial processes down the soil profile (0 – 100 cm) under cotton crops grown in Vertosols at the Australian Cotton Research Institute (ACRI), New South Wales. The overarching PhD aims were to i) Evaluate the potential for subsoil microbial activity to perform ecosystem services and ii) Determine the influence of crop rotation (continuous cotton and cotton-maize rotations) and sample time (3 sample points over two cropping seasons) on subsoil microbial processes. Microbial activity and biomass were assessed by respiration and stable oxygen isotope methodologies, whilst microbial diversity was measured utilising high throughput sequencing.
Microbial biomass and diversity analyses followed the expected trend of decreasing measurements with increasing depth, following the trends observed in international studies. Microbial activity was just as prevalent in subsoils for both field fresh and long-term (isotopic) assessments, which has not been observed in other studies. A lack of significant differences in microbial processes down the soil profiles under continuous cotton and cotton-maize systems was also observed. This research has led us to believe that the physical properties of Vertosols (self-mulching and formation of deep cracks) facilitate microbial activity in subsoils, thus having the potential to contribute to ecosystem services. It would also appear that the physical properties of Vertosols exert a greater influence than system management.
Publication Type: | Thesis Doctoral |
Fields of Research (FoR) 2008: | 050102 Ecosystem Function 050301 Carbon Sequestration Science 050303 Soil Biology |
Socio-Economic Objective (SEO) 2008: | 820301 Cotton 960904 Farmland, Arable Cropland and Permanent Cropland Land Management 961402 Farmland, Arable Cropland and Permanent Cropland Soils |
HERDC Category Description: | T2 Thesis - Doctorate by Research |
Description: | | Please contact rune@une.edu.au if you require access to this thesis for the purpose of research or study.
Appears in Collections: | School of Environmental and Rural Science Thesis Doctoral
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