• Energy Research
• 2020 close

Bioenergy is the main source of renewable energy today and it is expected to continue playing a key role in the decarbonisation of the European energy and transport sectors, a prerequisite to achieve the long-term targets of the EU, the Paris Agreement and sustainable development goals. The Implementation Plan of Action 8, Bioenergy and Renewable Fuels for Sustainable Transport (IP8) set detailed targets for the development, demonstration and scale-up of the sector. In order to achieve a step-change, six complementary stakeholders engaged in bioenergy and renewable fuels, joined forces to enable successful implementation within SET4BIO. The overall objective of SET4BIO is to support the full execution of the IP8, i.e. both for research and innovation lines and large-scale projects, acting as competence centre and complementary resource for the Implementation Working Group (IWG8). Industry, academia, institutes, EU Member States and Associated Countries as well as the European Institutions and functions play a key role for successful implementation of IP8. SET4BIO will propose solutions and pathways to overcome essential barriers identified in the IP8 and will engage and coordinate key stakeholders through a participatory approach. The project will identify and promote best practices for development, demonstration and scale-up through a competition-based innovation approach, monitor development, develop a financing roadmap as well as provide policy recommendations and disseminate results. A wide-ranging network must strive towards the same goal and SET4BIO will facilitate the coordination. Several beneficiaries are involved in the IWG8 set up by the European Commission. Commitment and understanding of SET-Plan ambitions on Industry and Member State/Associated Country level will be crucial to the successful implementation. SET4BIO will take an active role in supporting IWG8 and be a catalyst to facilitate the implementation of the actions which are set out in the IP8.

The Sun-to-X project will contribute to European Commission targets for clean energy for all and circular economy by developing a system for the conversion of solar energy into storable chemical fuel. While the concept of solar-to-chemical fuels has been around for decades, the technology has been limited by the economic viability and scalability of the technology. The Sun-to-X project focuses on using solar energy to produce a carbon-free, non-toxic, energy-dense, liquid fuel - Hydrosil, with very good long-term stability, which is applicable in the transport and energy sectors. We will firstly produce hydrogen as chemical intermediate through a photoelectrochemical device. This will then be converted to Hydrosil through a thermochemical reaction. The novelty of our proposal lies in the following three key aspects: 1. Overcoming the known practical challenges of high-performance photoelectrochemical fuel production by using membrane photoelectrode assemblies which can operate with solar energy using only ambient humidity as the water supply 2. Developing reactors for and demonstrating the renewable production of Hydrosil for the first time, using a thermochemical process (using concentrated solar light) 3. Demonstrating a completely decarbonised energy cycle with liquid fuels In addition, we will demonstrate the applicability of Hydrosil towards the transition to a circular economy, by using it for the valorisation of waste plastics.

1st year is the PG Diploma and research and Industry preparation Years 2-4 are a PhD at one of the CDT universities

Awaiting Public Project Summary

GeoUS will support increased research excellence in geothermal energy at VSB -Technical University of Ostrava, Czech Republic through close cooperation with Fraunhofer Institute, Germany and University of Vaasa, Finland. The ultimate goal is the development of multi-disciplinary research and innovation skills in the Czech Republic, focused on the fundamental and practical aspects of developing geothermal as a sustainable energy source. GeoUS will enable VSB to expand its network with leading research organisations in geothermal energy. It also involves young researchers to support future development of research activities impacting in the Moravia Region in line with the Regional and National Research and Innovation Strategy for Smart Specialization (RIS3 Strategy) and ESIF targets. The results will be widely shared with City Authority of Ostrava, Moravian-Silesian Regional Authority and also with authorities at national level. GeoUS will: 1. Transfer knowledge and build excellent research. 2. Increase scientific excellence in thermal characterization and mathematical modelling of heat flows and temperature fields and in measurement and control of energy flows. 3. Improve the scientific excellence and research capacity of VSB. 4. Increase the capacity of VSB for participation in future high-quality research activities and innovation in thermal energy in Central Europe. 5. Increase the interaction with and between the main players in the innovation process in Czech Republic for developing and exploiting geothermal energy. 6. Widen the visibility of VSB as a centre of excellence for thermal energy. 7. Engage with the public and citizens and young people on science related to thermal energy.

This project studies the dynamic response characteristic of the thermal energy storage (TES) coupled with the district heating network (DHN) and the innovative active control technology for the indoor thermal comfort with efficient load matching. Therefore, this study will develop a more accurate spatiotemporal dynamic simulation model for the TES-DHN emphasizing the thermal inertia and time-delay properties. The research will also develop an active control technology and optimization tool from the viewpoint of system design and operation to match the heat supply and demand more accurately. Moreover, reasonable experimental tests and case studies will also be designed and implemented to validate the developed methods and to disseminate research outcomes. Overall, this project will contribute new scientific findings and efficient engineering tools for active load matching in order to further improve energy efficiency and reduce CO2 emissions while improving the indoor thermal comfort.

1st year is the PG Diploma and research and Industry preparation Years 2-4 are a PhD at one of the CDT universities

Although renewable energy has always been a priority in UK, the incentives cuts for solar have slowed down new investments. There is a need for more efficient technologies to make the PV market more self-sustainable and preserve the thousands related jobs. Bifacial solar panels (BFPV) is one such technology: light can enter from both sides, thus generating more electricity. Unfortunately, there are issues limiting the wide adoption of the new, more efficient technology, the main one being the uncertainty in the forecast of energy output of BFPV. High uncertainty increases the risk for investors, limiting the proliferation of BFPV. The project builds on the cooperation between RINA and the National Physics Laboratory (NPL) developed during our A4I Round 3 Feasibility Study and aims to develop an innovative method to perform yield studies, with reduced uncertainty on the output of BFPV systems. The project focuses on a key problem in assessing the energy output of BFPV plant: the accurate evaluation of bifacial gain. In our Round 3 work, NPL introduced "effective" albedo (light reflected from the ground) as an input to RINA's energy output assessment method, which incorporates the varying light spectrum of the reflected light as well as the spectral response of solar panels into the analysis. The impact of this method on significantly reducing uncertainty on BFPV energy output estimations was demonstrated, and the energy estimates themselves rose for example sites. They key objectives of the current Round 5 project are: Develop the Round 3 methodologies to be applicable globally; Specify the hardware and procedural requirements for on-site albedo monitoring including uncertainty analysis. Incorporate uncertainties due to additional PV module factors into the bifacial gain estimation. Develop typical effective albedo datasets as a guide when site-specific data are unavailable. Feed into the working group for the improvement of the IEC 616724-1 standard. Determine the impact on financial risk by using different measurement and data analysis methods within BFPV energy forecasts. Benefits from the project will affect the whole value chain of energy, from generation to consumption. More reliable and better-understood measurements and data validation reduce the technical and financial risks of investors, consequently boosting BFPV investments. As a result, more power generated and higher efficiency guaranteed by the BFPV technology will favour a decrease in electricity price for consumers. This will also contribute towards reducing CO2 emissions and the UK's environmental impact.

This project studentship involves close collaboration with a team of researchers working on the development of perovskite solar-cell devices by spray-coating. Our research vision is to develop solar cells that are inherently non-planar and are continuously coated over 3-dimensional surfaces. As an exemplar, we will use composite materials such as carbon-fibre and other thermo-plastic polymers as the device substrate, as such materials can be easily formed into non-planar structures and can have very high strength-to-weight ratios. The systems we will develop will find potential applications as decentralized, mobile power sources for use in low-energy vehicles and aerospace-technology. Key to this integration is the development of spray-based techniques that permit PV to be coated over 3D surfaces in a seamless and unobtrusive fashion. The student will be charged with the development of techniques that will allow non-planar (curved) surfaces to be coated with various semiconductor materials by spray-coating. This will require a careful control of spray-based deposition techniques and control over drying rates. The student will explore techniques to control film drying-rates, and will also control the properties of the material solutions (inks) to be spray-cast using various viscosity modifiers. The student will then characterise the spray-cast films using a variety of microscopy and analytical techniques. Finally, the student will help fabricate and test the performance of the 3D photovoltaic devices created.

In order to meet the climate change mitigation objectives of the European Union as well as the objectives of the Paris Agreement, it is inevitable that the European Union phases out fossil fuel consumption in the power sector and decarbonizes fossil-fuel dependent industries. These industries are not spread evenly across the EU but concentrated in a number of carbon-intensive regions. Decarbonization will lead to deep structural changes with implications for regional economies, labour markets, as well as for the regions’ social, political, cultural and demographic composition. If not managed well, these structural changes may cause serious economic impacts, societal upheaval, aggravated social inequalities and hardship. To minimize such consequences it is necessary to better understand the patterns and dynamics of structural change in response to decarbonization at the regional level, to understand which parameters determine the pace of transformation as well as the capacity of regional actors to adapt and pro-actively create alternative structures. This project aims to enable these activities through highly integrated, inter- and transdisciplinary research working in close collaboration with regional stakeholders. It combines quantitative model-based research with qualitative in-depth analysis. The qualitative research will focus on four highly fossil-fuel dependent regions: Western Macedonia (Greece), Silesia (Poland), Ida-Virumaa (Estonia) and the Rhenish mining area (Germany). The regions were selected to cover a diverse set of different fuels, state of economic development, diversification of the regional economy, political economy, and spatial composition. This diversity will enable the project to derive generalizable insights about the patterns and dynamics of decarbonization and the corresponding structural adjustments that hold relevance for all carbon-intensive regions in the EU and its neighbouring countries.