• Energy Research
• OA Publications Mandate: No close
• 2015 close
• 2016 close

The UK has an ambitious and legally-binding target to reduce its carbon emissions by 80% by 2050 (relative to a 1990 baseline) as part of its commitment to limit its contribution to climate change. Achieving this target will require significant changes in how the UK sources its energy; reducing the use of fossil fuels and increasing the use of a mix of renewable technologies such as wind, solar, tidal and hydropower. The UK currently generates about 1.5% of its electricity from hydroelectric schemes, and although further large-scale development potential is limited, there is scope for exploiting small-scale and micro-hydropower resources (DECC, 2013). However, the potential impacts of such development on the environment and its stakeholders must be evaluated and minimised where possible. This NERC Policy Placement at the Environment Agency will gain a detailed understanding of the different areas of potential concern associated with the development of low head hydropower schemes through consulting with a wide range of stakeholders initiated by a project launch workshop event. External stakeholders may include representatives from rivers user groups (e.g. the Angling Trust, Canal & River Trust, Inland Waterways Association, National Association of Boat Owners, the British Canoe Union and the Ramblers Association), environmental bodies (e.g. Rivers Trusts, Wildlife Trusts, the RSPB, Natural England, English Heritage, Environment Agency, DEFRA), energy organisations (the National Grid, DECC), and the British Hydropower Association. The understanding gained through consultation with stakeholders will be used to inform a life-cycle analysis that compares the environmental impacts of low-head hydropower schemes against all other forms of electricity generation across a comprehensive list of factors (global warming potential, land footprint, water footprint, abiotic depletion potential, acidification potential, eutrophication potential, aquatic ecotoxicity potential), including those factors identified through consultation with stakeholders. Systematic and transparent data and literature searches will be used, as recommended in Dr Bilotta's recent open-access publications co-authored by Defra's Chief Scientific Advisor (Bilotta et al., 2014a;b), to ensure that the findings of the life-cycle analysis are traceable and can be updated in light of improvements in the technologies which can occur rapidly. This comparative life-cycle analysis will enable stakeholders and policy-makers to make a better informed decision about the relative merits and drawbacks of different forms of electricity generation on their respective areas of concern. The project will also identify specific design and siting aspects of low head hydropower schemes that are associated with the most and the least environmental impacts, through collating and statistically-analysing existing monitoring data collected routinely in England and Wales as good practice (Environment Agency, 2014), before and after installation of hydropower facilities. This analysis will be published in a peer-reviewed journal and used, where appropriate, to update the good practice guidelines on hydropower development (Environment Agency, 2014). Ultimately, these guidelines will be used to optimise the design of future hydropower schemes in England and Wales, to minimise their impact and maximise their environmental and social sustainability. References: Bilotta, G. S., Milner, A. M., & Boyd, I. (2014a). On the use of systematic reviews to inform environmental policies. Environmental Science & Policy, 42, 67-77. Bilotta, G. S., Milner, A. M., & Boyd, I. L. (2014b). Quality assessment tools for evidence from environmental science. Environmental Evidence, 3(1), 1-14. DECC (2013) https://www.gov.uk/harnessing-hydroelectric-power Environment Agency (2014) https://www.gov.uk/government/collections/hydropower-schemes-guidelines-and-applying-for-permission

The aim of this technical feasibility project is research the feasibility of applying proven technology, performance management and efficiency principles from the aerospace sector to the solar energy sector through prototyping of advanced predictive analytics leveraging the technical and market innovations provided by the Internet of Things (IoT). The study will have a stakeholder group of solar companies.

Recent reports indicate that a significant impact of accumulation of dust and other debris on the surface of photovoltaic modules causes a decrease in the incoming solar irradiance, with typical power losses of 10-15%, or even up to 50% in some cases reported. Durable highly repellent coatings based on advanced, nanostructured, low energy materials can provide a permanent solution to prevent the accumulation of dirt on the transparent top layer of a PV system. The primary objective of the SOLplus project is to determine the technological, commercial, and economic viability of such a low surface energy coating for use in the solar PV market. The main technology and commercial objectives for this product will be to deliver a durable coating that prevents the accumulation of dirt/dust on glass and plastic solar substrates, is cost-effective in its application method, and demonstrates real and tangible benefits to the end user (maintenance-free and avoidance of expensive cleaning procedures). Technology validation for the solar PV market and a refinement of our assessment of the market opportunity during the project will allow for a better focus on the market needs