Large scale deployment of renewable energy (RE) is key to comply with the GHG emissions reduction set by the COP21 agreement. Despite cost competitive in many settings, RE diffusion remains limited largely due to its variability. This works as a major barrier to RE’s integration in electricity networks as knowledge of power output and demand forecasting beyond a few days remains poor. To help solve this problem, S2S4E will offer an innovative service to improve RE variability management by developing new research methods exploring the frontiers of weather conditions for future weeks and months. The main output of S2S4E will be a user co-designed Decision Support Tool (DST) that for the first time integrates sub-seasonal to seasonal (S2S) climate predictions with RE production and electricity demand. To support the dissemination of climate services, a pilot of the DST will be developed in two steps. The first will draw on historical case studies pointed as relevant by energy companies - e.g. periods with an unusual climate behaviour affecting the energy market. The second step will improve probabilistic S2S real-time forecasts built up into the DST and assess their performances in real life decision-making in these companies. This process will be co-designed with consortium’s partners which represent different needs and interests in terms of regions, RE sources (wind, solar and hydro) and electricity demand. Besides the partners, S2S4E will engage other users from the energy sector as well as other business areas and research communities to further explore DST application and impact. As a result, DST will enable RE producers and providers, electricity network managers and policy makers to design better informed S2S strategies able to improve RE integration, business profitability, electricity system management, and GHG emissions’ reduction. The long-term objective is to make the European energy sector more resilient to climate variability and extreme events.

LiCORNE aims to establish the first-ever Li supply chain in Europe. The goal is to increase the European Li processing and refining capacity for producing battery-grade chemicals from ores, brines, tailings and off-specification battery cathode materials. This supply chain encompasses five large primary resource owners (including one of the world leader in Li production) having resources of ~7.8 Mt lithium carbonate equivalent (LCE), in which 2.7 Mt LCE are located in Europe. The European primary resources that are considered in LiCORNE would be enough to supply ~3000 GWh of batteries (i.e., ~10 years to the expected 300 GWh/year production capacity in Europe by 2030). Additionally, the value chain includes a cathode manufacturer who will be able to reuse valuable Li, Co and Ni that will be recycled from waste cathode material, and one producer and distributor of battery-grade Li-chemicals. LiCORNE will investigate 14 different groundbreaking technologies that have been selected for their potential to operate at low CAPEX and OPEX, low carbon footprint, flexibility and industrial scalability. Those technologies are led by 8 top R&D centers in Europe to tackle the main bottlenecks in Li processing and recovery. During 2.5 years, R&D partners will investigate those technologies and bring their TRL from 2 to 4. After this phase, and guided by LCA and LCCA, the most promising technologies will be selected for upscaling to TRL5. During this phase a prototype system will be constructed and demonstrated at TRL5 to produce ~1 kg of battery-grade Li-chemicals (i.e., LiOH∙H2O, Li2CO3 or Li-metal) from ores, brines, tailings and waste cathode material, with the recycling of Co and Ni from the latter. Results will be communicated and disseminated to a wide range of stakeholders and a first business model for a full and optimized Li supply chain in Europe will be established based on the results of the project and cost of Li produced.

The ReaLCoE consortium is happy to submit a well-prepared proposal, founded on a highly experienced and tight-knit group in discussion since early 2017. ReaLCoE aims to accelerate a new generation of competitive and subsidy free clean energy from offshore wind energy converters (WEC) with a high performance 12+MW demonstration turbine. Our WEC technology platform developments are designed to be competitive and scalable, consolidating scientific knowledge and operational experience for a swift evolution towards 14-16 MW rated capacities. Today, only less than 30% of the cost for electricity from large offshore wind energy converters incur from the turbine itself. ReaLCoE will work to optimise innovation across the whole value chain; from initial turbine design to equipment handling in the port, to testing, financing installation and the final customer to substantially reduce the Levelised Cost of Electricity (LCoE) of offshore wind. The consortium is led by a pioneer in the sector, Senvion, who has brought together some of Europe’s most experienced and talented actors in both on- and offshore wind energy to demonstrate a 12+MW WEC. After a period of strong market consolidation, Senvion and its partners aim to jointly enter a competitive market of offshore wind energy in the 12+MW turbine class. We are confident that ReaLCoE will have a global impact on offshore wind energy market, reinforcing Europe’s technological leadership and bringing growth and job opportunities to the industrial base. Not only in the wind energy sector through the manufacturing, installation and operation of 12+MW WEC in a competitive environment; but also through the provision of cheap, clean energy across an integrated system of renewables. This paves the way for a turbine generation with rated capacities of 14-16MW and triggers hundreds of millions in investment into the European clean tech sector.

DESTRESS is aimed at creating EGS (Enhanced geothermal systems) reservoirs with sufficient permeability, fracture orientation and spacing for economic use of underground heat. The concepts are based on experience in previous projects, on scientific progress and developments in other fields, mainly the oil & gas sector. Recently developed stimulation methods will be adapted to geothermal needs, applied to new geothermal sites and prepared for the market uptake. Understanding of risks in each area (whether technological, in business processes, for particular business cases, or otherwise), risk ownership, and possible risk mitigation will be the scope of specific work packages. The DESTRESS concept takes into account the common and specific issues of different sites, representative for large parts of Europe, and will provide a generally applicable workflow for productivity enhancement measures. The main focus will be on stimulation treatments with minimized environmental hazard (“soft stimulation”), to enhance the reservoir in several geological settings covering granites, sandstones, and other rock types. The business cases will be shown with cost and benefit estimations based on the proven changes of the system performance, and the environmental footprint of treatments and operation of the site will be controlled. In particular, the public debate related to “fracking” will be addressed by applying specific concepts for the mitigation of damaging seismic effects while constructing a productive reservoir and operating a long-term sustainable system. Industrial participation is particularly pronounced in DESTRESS, including large energy suppliers as well as SMEs in the process of developing their sites. The composition of the consortium involving major knowledge institutes as well as key industry will guarantee the increase in technology performance of EGS as well as an accelerated time to market.