Waste heat recovery systems can offer significant energy savings and substantial greenhouse gas emission reductions. The waste heat recovery market is projected to exceed €45,0 billion by 2018, but for this projection to materialise and for the European manufacturing and user industry to benefit from these developments, technological improvements and innovations should take place aimed at improving the energy efficiency of heat recovery equipment and reducing installed costs. The overall aim of the project is to develop and demonstrate technologies and processes for efficient and cost effective heat recovery from industrial facilities in the temperature range 70°C to 1000°C and the optimum integration of these technologies with the existing energy system or for over the fence export of recovered heat and generated electricity if appropriate. To achieve this challenging aim, and ensure wide application of the technologies and approaches developed, the project brings together a very strong consortium comprising of RTD providers, technology providers and more importantly large and SME users who will provide demonstration sites for the technologies. The project will focus on two-phase innovative heat transfer technologies (heat pipes-HP) for the recovery of heat from medium and low temperature sources and the use of this heat for; a) within the same facility or export over the fence; b) for generation of electrical power; or a combination of (a) and (b) depending on the needs. For power generation the project will develop and demonstrate at industrial sites the Trilateral Flash System (TFC) for low temperature waste heat sources, 70°C to 200°C and the Supercritical Carbon Dioxide System (sCO2) for temperatures above 200°C. It is projected that these technologies used alone or in combination with the HP technologies will lead to energy and GHG emission savings well in excess of 15% and attractive economic performance with payback periods of less than 3,0 years.

This proposal describes the third core project of the Graphene Flagship. It forms the fourth phase of the FET flagship and is characterized by a continued transition towards higher technology readiness levels, without jeopardizing our strong commitment to fundamental research. Compared to the second core project, this phase includes a substantial increase in the market-motivated technological spearhead projects, which account for about 30% of the overall budget. The broader fundamental and applied research themes are pursued by 15 work packages and supported by four work packages on innovation, industrialization, dissemination and management. The consortium that is involved in this project includes over 150 academic and industrial partners in over 20 European countries.

The 2D Experimental Pilot Line (2D-EPL) project will establish a European ecosystem for prototype production of Graphene and Related Materials (GRM) based electronics, photonics and sensors. The project will cover the whole value chain including tool manufacturers, chemical and material providers and pilot lines to offer prototyping services to companies, research centers and academics. The 2D-EPL targets to the adoption of GRM integration by commercial semiconductor foundries and integrated device manufacturers through technology transfer and licensing. The project is built on two pillars. In Pillar 1, the 2D-EPL will offer prototyping services for 150 and 200 mm wafers, based on the current state of the art graphene device manufacturing and integration techniques. This will ensure external users and customers are served by the 2D-EPL early in the project and guarantees the inclusion of their input in the development of the final processes by providing the specifications on required device layouts, materials and device performances. In Pillar 2, the consortium will develop a fully automated process flow on 200 and 300 mm wafers, including the growth and vacuum transfer of single crystalline graphene and TMDCs. The knowledge gained in Pillar 2 will be transferred to Pillar 1 to continuously improve the baseline process provided by the 2D-EPL. To ensure sustainability of the 2D-EPL service after the project duration, integration with EUROPRACTICE consortium will be prepared. It provides for the European actors a platform to develop smart integrated systems, from advanced prototype design to small volume production. In addition, for the efficiency of the industrial exploitation, an Industrial Advisory Board consisting mainly of leading European semiconductor manufacturers and foundries will closely track and advise the progress of the 2D-EPL. This approach will enable European players to take the lead in this emerging field of technology.

ICARUS will upcycle waste material resources of most selected process industries (covering minerals, cement, ceramic, non-ferrous metals, steel, water, pulp&paper and chemical ones) to achieve circular and sustainable process industries overcoming their final application in construction sector. This project will accelerate the process industry uptake and contributing towards the developed education and skills activities and outcomes in this area as well as linking all value chain from industrial players recyclers, public authorities, and standardisation actors. ICARUS tackles resources usage in the construction sector (housing and infrastructure), accounting for 50% of the total material extraction, and being responsible for more than 35% of waste streams in the EU. Furthermore, the circular economy in the sector is still at a very early stage, with an estimated level of circularity for the EU of 12.4% material use rate in the year 2021. ICARUS approach aims to give technological support to stakeholders of energy-intensive and construction industries as key players for the transition to a more green and digital processes industries supported by standardization aspects to promote values and a resilient, green and digital Single Market and business models including co-creation and co-design to successful market implementation. ICARUS will represent a breakthrough in the research and demonstration of new technologies to upgrade Secondary Raw Materials ensuring similar quality as primary raw materials, of three waste streams to improve circular economy principles in several intensive industries with its implementation in the construction sector, to improve circular economy principles in P4P process industries. These new technologies will be demonstrated throughout 3 demo cases: 1-Upcycling of Lithium Aluminosilicate Residue;2-Upcycling of SRMs from urban waste cellulose;3-Upcycling of steelmaking slags via Carbon Capture and Storage .

This proposal describes the third stage of the EC-funded part of the Graphene Flagship. It builds upon the results achieved in the ramp-up phase (2013 - 2016) and the first core project (2016 - 2018), and covers the period April 2018 - March 2020. The progress of the flagship follows the general plans set out in the Framework Partnership Agreement, and the second core project represents an additional step towards higher technology and manufacturing readiness levels. The Flagship is built upon the concept of value chains, one of which is along the axis of materials-components-systems; the ramp-up phase placed substantial resources on the development of materials production technologies, the first core project moved to emphasise components, and the second core project will move further towards integrating components in larger systems. This evolution is manifested, e.g., in the introduction of six market-motivated spearhead projects during the Core 2 project.