- Biological soil communities (BSC) at the soil surface perform vital ecosystem functions, including C and N fixation, and protection of the soil surface from erosion.
- You will quantify the ecosystem functions of BSC in temperate soils and investigate the way in which they will be affected by climate change, including extreme weather events
- You will use a wide variety of cutting edge microbiological, molecular biology and gas analysis techniques, including novel gas sensor technologies for continuous reporting of both greenhouse gas emissions from soil and other soil metabolic activity.
Soil possesses a complex biological layer at the surface, comprised of cyanobacteria, bacteria, algae and bryophytes. These have been well studied in deserts, where they have considerable environmental importance because of their role in nitrogen and carbon fixation, determining water infiltration and evaporation and protecting the soil against erosion. We have shown that such biological soil crusts (BSC) can also form in temperate soils, and have similar biological compositions to those in desert soils, suggesting that they may perform similar, vital, ecosystem roles.
Climate change is affecting weather patterns, increasing the frequency, magnitude and duration of extreme weather events such as high temperature, drought, flooding and extreme rainfall. Since BSC inhabit the interface between the atmosphere and the soil, the resilience of BSC to changes in weather patterns is likely to play a key role in determining how extreme weather events impact soil sustainability and resilience of its ecosystem functions.
In this project you will investigate the functions of BSC in temperate soil, and the way in which these will be impacted by climate change, including extreme weather events.
You will investigate the ecosystem functions of BSC including their role in the production and consumption of greenhouse gases, and the extent to which they fix N from the atmosphere. This will be complemented with molecular profiling of functional genes and metagenomic profiling, to provide a mechanistic understanding of the way in which BSC drive soil biogeochemical cycles. You will also investigate the potential of the BSC to alter the physical structure of the soil surface and to protect the soil against erosion. You will use the unique rainfall simulation facilities at Cranfield to test the resilience of BSC ecosystem functions to future climatic regimes and extreme weather events. Within the programme you will investigate the potential for using sensor technology which is currently being developed at Warwick to provide continuous reporting of greenhouse gas and other metabolite emissions from soil, enabling fine level resolution of BSC community responses to weather.
Training and Skills
Training will be provided in a wide range of molecular techniques (DNA extraction, PCR, sequencing), metagenome sequencing and bioinformatics, and in environmental analysis techniques, including soil physical and biological characterisation. Access to rainfall simulation facilities will also bring skills in replicating the dynamic processes of soil erosion at realistic spatial and temporal scales. You will also receive training in a variety of methods for analysis of trace gas analyses, including sensor technologies. Specifically covering use of equipment for the real-time/long-term analysis of soil metabolic functions, as well as high-end lab based equipment (such as GC-TOF-MS).
Year 1: Development of sensor technologies and functional analysis of soil crust communities
Year 2: Characterise effects of weather treatments on BSC and their functional roles
Year 3: Fine level resolution of GHG and metabolite emissions from BSC using sensor techniques
Professor Gary Bending
School of Life Sciences
University of Warwick