GIANCE offers innovative solutions to environmental challenges and establishes a holistic, integrated, and industrial-driven platform for the design, development, and scalable fabrication of the next generation of cost-effective, sustainable, lightweight, recyclable graphene and related materials (GRM)-based multifunctional composites, coatings, foams, and membranes (GRM-bM) with enhanced properties (e.g. thermal, mechanical, chemical), functionalities (e.g. wear, corrosion, chemical and fire resistance, hardness and impact resistance, high temperature resistance, structural health monitoring, ultralow friction surfaces), and as enablers for hydrogen storage. GIANCE will also advance manufacturing processes, enhancing synthesis and stability and reducing environmental impact. Such GRM-bM and manufacturing capabilities will allow robust connections with end-users and thus develop and qualify the commercial propositions to high TRLs. GIANCE will develop, demonstrate, and validate the efficacy of GRM-enabled products (11 use cases) which will underlie future technologies for different sectors (e.g. automotive, aerospace, energy (hydrogen economy) and water treatment). GIANCE also supports the innovation output and industrialization efforts of the Graphene Flagship initiative, building a credible pathway for the newly accumulated knowledge to impact EU industry and society. GIANCE will support a strong EU value chain in translating technology advances from TRL4-5 into concrete innovation opportunities and production capabilities (TRL6-7), with first-mover market advantages of scale in the defined industrial sectors. The consortium consists of 23 partners from 10 countries, representing the full value chain, with leading OEMs, large industries, world-class research and education organisations, and innovative SMEs. GIANCE is designed to ensure maximum impact for the defined industries and society as a whole, significantly contributing to the evolving field of GRM.

Borealis project presents an advanced concept of machine for powder deposition additive manufacturing and ablation processes that integrates 5 AM technologies in a unique solution. The machine is characterized by a redundant structures constituted by a large portal and a small PKM enabling the covering of a large range of working cube and a pattern of ejective nozzles and hybrid laser source targeting a deposition rate of 2000cm3/h with 30 sec set-up times. The machine is enriched with a software infrastructure which enable a persistent monitoring and in line adaptation of the process with zero scraps along with number of energy and resource efficiency optimization policies and harvesting systems which make the proposed solution the less environmental invasive in the current market. Borealis idea results from a consortium composed by the excellence of developers of worldwide recognized laser machines and advanced material processing together with the highly precision and flexible mechatronic designers. These two big clusters decided to join their expertise and focus on new manufacturing challenges coming from complex product machining in the field of aerospace, medtech and automotive represented by major partners in the market. Borealis project targets a TRL 6 and will provide as outcome of three years work two complete Borealis machine in two dimensions – a lab scale machine and a full size machine – which are foreseen to be translated into industrial solution by 2019.

The Mediterranean Sea and its surrounding regions support a diverse variety of essential socioeconomic activities. It is one of the highly exploited water ways and the influence of anthropogenic activities on its marine habitats and ecosystems has grown significantly since the industrial revolution. Because of this, the Mediterranean Sea basin is very vulnerable to chemical contamination and buildup. To safeguard the Mediterranean Sea basin from contaminants for emerging concerns (CoEC), iMERMAID will integrate, coordinate, and synergize innovative preventive, monitoring, and remediation solutions. iMERMAID will build an evidence-based multidimensional framework that will guide policymaking and transform societal perceptions to reduce CoEC usage, emissions, and pollution. Furthermore, next generation sensor and remediation solutions will be developed within iMERMAID to monitor and remove prioritized chemicals from its source while reducing upstream pollution. iMERMAID builds an ideal interdisciplinary team by bringing together prominent SMEs, researchers, regulators, and innovation professionals who have been essential in improving the knowledge and awareness of CoEC. Beyond state-of-the-art techniques, iMERMAID will strive to strengthen regulations against CoEC, expand economic possibilities and competitiveness, improve the standard of living for EU residents, while preventing the accumulation of chemical pollution in the Mediterranean Sea basin. iMERMAID will empower the efforts to create a zero pollution, contaminant free waters by enabling the Chemical Strategy's goals to become a practical reality.

CLAIM focuses on the development of innovative cleaning technologies and approaches, targeting the prevention and in situ management of visible and invisible marine litter in the Mediterranean and Baltic Sea. Two innovative technological methods will be developed, a photocatalytic nanocoating device for cleaning microplastics in wastewater treatment plants and a small-scale thermal treatment device for energy recovery from collected litter on board ships and ports. An innovative floating boom for collecting visible litter and a method to measure microlitter on board ships (Ferrybox) will be developed. The proposed cleaning technologies and approaches prevent litter from entering the sea at two main source points, i.e. wastewater treatment plants and river mouths. Effectiveness of developed devices and methods will be demonstrated under real conditions. Additionally, CLAIM will develop innovative modeling tools to assess the marine visible and invisible plastic pollution at basin and regional scales (Saronikos Gulf, Gulf of Lyon, Ligurian Sea, Gulf of Gabes and Belt Sea). An ecosystems approach will be followed to evaluate the potential benefit from proposed litter cleaning methods to ecosystem services. New business models will be developed to enhance the economic feasibility for upscaling the innovative cleaning technologies, taking into account the existing legal and policy frameworks in the CLAIM countries, as well as acceptance of the new technologies by their end-users and relevant stakeholders. The data and information produced will be made available to policymakers, stakeholders and end-users in a user-friendly format,both meaningful and tailored to each stakeholder group. CLAIM aims at the same time to raise public awareness with respect to having healthy oceans and seas, clean of litter and pollutants, and hence the importance of reducing marine (macro, micro and nano) pollution in European seas and beyond towards restoring marine ecosystems based on a circular economy.

WISE sets a new frontier for product complexity by shifting the focus from geometry to functionality, introducing features such as self-healing, triggered biomolecule diffusion, and smart repairing. This disruption redefines current design methodology, leveraging advanced AI-aided engineering and multi-scale, multi-process manufacturing to achieve unprecedented complexity. WISE has the potential to drive a discontinuity in the growth of the European industry by convincingly demonstrating an innovative, competitive, and scalable manufacturing concept based on a single machine that integrates macroscale processing (i.e., DED via hybrid blue-IR lasers) and micro-nano scale processing (i.e., fs and ns laser ablation, 2PP, DALP). WISE will deliver a TRL7 multi-process machine integrating high-precision, multi-scale techniques for producing complex multifunctional products. The project will demonstrate the machine's performance, flexibility, and precision by producing three complex hybrid products in MedTech, Aerospace, and Power generation sectors. The project builds upon TRL5-validated results from previous H2020 projects, which have brought significant innovations in the field of advanced manufacturing and enabling technologies. The work plan includes a final demonstration to validate the solution through the production of complex components based on end-user requirements. Upon completion, WISE will be further developed to reach TRL9 within 24 months, leading to its commercial launch as a multi-process manufacturing station. The WISE consortium is composed of 16 partners, including 8 SMEs, 4 LE, and 4 RTD. Their expertise covers mechatronics, intelligent nanostructured components, laser-material interaction, high-precision machines and tools. The project partners form a cluster of European countries playing crucial roles in the production of functionalized products with smart functionalities, adaptive photonic solutions, and advanced mechatronic systems.