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A research partnership between Edge Hill University and Sefton Metropolitan Borough Council developed innovative methods of identifying gaps in knowledge and understanding about sedimentary coastal dynamics and investigating practitioner needs. The partnership enabled the dissemination of scientific information to audiences across the wider community. The partnership provided a framework which enabled and enhanced integrated coastal zone management (ICZM). Within this framework coastal zone managers were supported in the development of adaptation and mitigation strategies, taking account of both long and short term environmental change. Policy and management decisions are now based upon sound scientific evidence wherever possible, ascertained by research where time allows, with significant scientific, social and policy benefits. Practice elsewhere on the UK's Irish sea coast, and elsewhere in the EU, has been influenced.
Protecting London from the threat of flooding is of prime importance to the nation. Work in the Unit on regional sea-level rise and on the effect of storm surges was used in the Environment Agency's Thames Estuary 2100 (TE2100) plan to assess potential change in risk. The Unit's work estimated a very unlikely maximum rise in sea level of 2.7m by 2100, considerably lower than the previous worst-case scenario of 4.2m. It confirmed that 90 centimetres was the figure that should be used for developing the plan. TE2100 concluded that a second Thames Barrier (estimated cost £10-20 billion at today's prices) would not be needed not by 2030, but may be needed by 2070. Our results have been used to define procedures for the monitoring of regional sea and Thames water levels over the next few decades, and to review decision-making procedures to ensure that the risk of flooding in London is kept within acceptable levels, while avoiding unnecessary costs
Exceptional rainfall in June 2007 lead to widespread flood damage in the UK; Hull was particularly badly affected with 8600 houses and 1300 businesses flooded, the closure of schools and cancellation of many events. At the instigation of the City Council, Hull University geographers produced two influential reports that explained how and why the flooding happened and what might be done to improve flood readiness for the future.
The reports had impact at a national scale. They fed into the findings of the House of Commons Select Committee on Environment, Food and Rural Affairs (published 7 May 2008) and the Pitt Report (a Government Independent Review, published 25 June 2008), which were both tasked with addressing the summer 2007 floods. Significant elements of `The Flood and Water Management Act' (2010), which was enacted subsequently, were informed by our research.
The reports also impacted at the regional scale. Their findings were adopted by Hull City Council, the Environment Agency and Yorkshire Water. Therefore, our research also shaped several practical strategies to improve flood prevention policies and minimise danger, damage, distress and expense in future floods.
Angela Gurnell's research on the geomorphology, hydrology and plant ecology of urban water courses has led to the development of important new tools for the biophysical assessment and improved management of urban rivers. Known as the Urban River Survey (URS), these tools are accessed by the Environment Agency and River Trusts across London, and their application is supported with workshops and guidance provided by Gurnell and her team. The URS has been used to deliver morphological quality indicators for rivers across London; to appraise river restoration schemes; to develop catchment management plans; and to assess long-term changes in rivers. It is currently being developed to quantify and set targets for river improvement schemes in relation to their impact on river ecosystem services. Gurnell's work has made a distinct contribution to urban river improvements in Britain and Europe, particularly through her leadership in developing a European framework for assessing hydromorphology.
Research by the University of Southampton into river processes and restoration has contributed significantly to the adoption of fluvial geomorphology as a tool for river management. The research quantified for the first time, the cost of sediment management in rivers to the UK economy and environment, arguing that improvements could be achieved by applying fluvial geomorphology. The research developed new evidence, tools and training that were adopted by river management agencies and consultants for the scoping, assessment and planning of projects. This has resulted in cost-savings through reduced river maintenance, improved river environments, and the creation of a new employment market for graduates with geomorphological training.
Surface water runoff in urban areas makes a significant contribution to pollution of lakes and rivers, but historically is poorly addressed in catchment models. The School of Geography (SoG) developed a Geographic Information System (GIS) model and supporting database to quantify urban source area loadings of 18 common and priority pollutants. This knowledge improves catchment models and supports impact assessment and mitigation planning by environment managers. The research has been exploited on behalf of the Department for Energy, Food and Rural Affairs (DEFRA), the Welsh Assembly, and the UK water industry (UK Water Industry Research — UKWIR, and United Utilities). The research has had three distinct impacts: 1) its use addressing EU Water Framework Directive obligations; 2) its on-going influence on construction industry guidance; and 3) the commercialisation of its stormwater pollutant coefficient database for Sustainable Urban Drainage Systems (SUDS) planning software.
The water industry sources significant drinking waters from peatland catchments and faces major water discolouration problems due to dissolved organic carbon (DOC) caused by peat degradation. DOC has to be removed to meet strictly regulated drinking water standards and to eliminate disinfection by-products. One proven, but expensive industry solution uses Magnetic Ion Exchange (MIEX) at treatment works. Research at the School of Geography (SoG) investigated catchment management as a potentially longer term, more sustainable treatment solution that addresses the problem at source. Yorkshire Water (YW) has subsequently adopted recommended practices, and has invested [text removed for publication] in catchment solutions yielding wider environmental benefits.
For over 40 years, the Urban Pollution Research Centre has undertaken pioneering work in understanding the sources, behaviour and fate of urban diffuse pollution and its mitigation using sustainable urban drainage systems (SUDS). Relevant impacts claimed here include the adoption of SUDS into UK practice and legislation, the role of SUDS as key components in achieving EU Water Framework Directive (WFD) requirements and the embedding of our research within national best practice guidelines. In response to recent policy drivers, we are collaborating with Arup to commercialise SUDSloc and are informing policy developments in the fields of diffuse pollution mitigation and urban ecosystem services.
Mumford and Tallant engaged in consultancy work for IT companies, with both interactions leading to substantial positive benefits for commercial partners. Though `early stage impacts', each consultancy has generated both commercial value and a change in software design of a key product.
Through Mumford's consultancy, research led to significant changes to the development of a database tool developed by a national IT company, FACE Recording and Measurement Systems. This, in turn, has led to a patent application. FACE recently received an offer of $5m (US) for a product based upon the tool.
Through Tallant's consultancy, research led to important changes to the development of an online calendar/event planner tool, developed by a Canadian software company—Time.ly. It also led to Time.ly being able to engage a wider audience. The financial value of such a company depends upon the number of users they can engage. Time.ly were recently valued at $8.4m (CAN).
Between them, Mumford and Tallant have made significant contributions to companies or products valued at over £8m.
Research undertaken by Professor Phil Jordan on nutrient pollution from land to waters has led to significant changes in government policy and in expectations for Water Framework Directive (WFD) and Waste Directive (WD) compliance in Ireland. The WFD is European wide legislation requiring that all water-bodies should be of at least good ecological status by 2015. His research has provided unequivocal scientific evidence that bio-physical lag times preclude the achievement of WFD water quality targets from diffuse source pollution by 2015. This has led to targets for good water quality in all River Basin Management Plans being extended without threat of European fines. Further, inclusion of Jordan's research on the specific environmental risk of rural point source pollution in assessments of septic tank system risk has resulted in the overturning of a European Court ruling under the Waste Directive, and the consequent lifting of daily fines of €19,000.