Abstract
This project will bring together an interdisciplinary team of experts from across academic, policy and stakeholder organisations in order to prioritise and plan a response to the pressing science needs associated with resource recovery from waste. Specifically, the project will explore nutrient recovery from excessive aquatic plant and algal biomass production in nutrient enriched waters (e.g. ponds, constructed farm wetlands, sustainable urban drainage systems and natural waterbodies) and, crucially, will integrate economic, social, environmental and health-related dimensions that cut across traditional academic disciplines. Thus, the overall aim of this project is to facilitate the exchange of knowledge across the disciplinary boundaries of biology, geography, soil and water science, microbiology, human behaviour, risk perception, waste management, economics and catchment management. In turn, we will develop a comprehensive, holistic and targeted programme of research to close the loop on nutrient transfer from land to water. This will be underpinned by understanding and quantifying the risks, opportunities and multiple benefits of recycling excessive aquatic plant and algal biomass back to agricultural land. The project will therefore contribute to a paradigm shift in current conceptualisation of waste management to redress the current imbalance of focus on economic benefits of recovering resources from waste. In a wider context, effective and sustainable waste management must take account of the often unquantified and uncertain trade-offs for managing wastes across the environment. For example, recovering nutrients from aquatic plant and algal biomass makes economic sense because fertiliser costs are soaring due to shortages in mineral supply; however, this is only one part of a complex socio-economic-ecological system. We need to couple economics with the safeguarding of human health and protection of key ecosystem services, such as the provision of clean and safe recreational and drinking water, and appreciate the social and political barriers that may hinder or promote efficient nutrient recovery from this waste by-product. While we know that anthropogenic inputs of nutrients to aquatic systems can be assimilated in aquatic biomass we have little knowledge on how pathogens and toxins may be recycled through agroecosystems following reapplication of this biomass to land, and poor understanding of nitrogen and phosphorus release rates from non-composted and composted biomass. Furthermore, the potential role for aquatic plant and algal biomass to be made into biochar (charcoal) as a novel approach to re-cycle nutrients and store carbon in soil (to offset emissions of carbon dioxide) is another dimension of resource recovery from waste by-products that might deliver multiple benefits and ecosystem services for wider society. There are a number of additional policy related dimensions to debate including whether there is an issue surrounding the classification of recycled biomass as non-waste in terms of regulation and licensing. Our team is well equipped with the expertise to develop core work-packages needed for a well balanced research agenda in recycling biomass to agricultural land. The project team are therefore tasked with framing some important emerging questions that will need innovative science and integrated solutions for 2020 and beyond. By pooling the cross-disciplinary expertise assembled in this catalyst grant we will identify where improvements in fundamental understanding are necessary to deliver step changes in waste management for environmental benefits and help refine regulatory policy and practice to support this.
United Kingdom