The main goal of SUNSHINE is to develop and implement S&SbD strategies for products enabled by multi-component (advanced) nanomaterials (MCNM), including high aspect-ratio nanomaterials (HARNs). To this end, the project will generate essential knowledge, tools and data on the exposure, hazard and functionality characteristics of these materials, especially those arising from their unique properties and interactions (e.g. mixture effects due to the multi-component nature of the materials). To facilitate the uptake and utilisation of the S&SbD strategies by industry, especially SMEs, we will deliver them as part of a user-friendly e-infrastructure designed to: (1) facilitate collaboration and information exchange between actors along nanotechnology supply chains (developers, producers, downstream users) to promote the development and implementation of S&SbD strategies for MCNM-based materials, products and processes; (2) support SMEs and large industries in the selection and application of simple, robust and cost-effective experimental, modelling and grouping/read-across approaches to acquire/generate the data needed to test the effectiveness of the S&SbD strategies; (3) enable risk-benefit analysis of the S&SbD-modified materials and products at each stage of the innovation process to ensure that they are safe for the human health and the environment without compromising their technical and/or commercial probability of success The S&SbD strategies that are effective in reducing the risks from MCNMs, while retaining product performance and economic viability, will be proposed for full scale industrial implementation. In addition, the project will contribute to Regulatory Preparedness by providing recommendations on improvement and adaptation of the current regulatory hazard, exposure and risk assessment guidance (e.g. REACH, Biocides, Consumer Products, Food and Feed, Medical Technologies) and standard guidelines (OECD, ISO, CEN) for MCNMs.

The main objective of ENCORE is to increase the share of renovated stock in Europe and worldwide by providing effective and affordable BIM tools that cover the whole renovation life-cycle (from data collection to project execution, and commissioning/delivery). It will tackle energy efficiency and comfort parameters, involving all the actors in the process (architecture studios, designers, constructors, tenants, or public administration), and facilitating information exchange among all the parties. To achieve this objective ENCORE proposes the creation of a system that integrates services for data acquisition from the buildings like Static LiDAR setups, and LiDAR or photogrammetry equipment embarked in UAVs. It will also allow to involve dwellers in the process by providing them with mobile tools to capture images or other in-doors information. It also provides support to architects and designers in the creation of the 3D models from the acquired data, automatically identifying and classifying the constructive elements, and allowing them to complete the model with existing BIM resources. They will be able to modify the model, presenting the energy efficiency gains of different renovation alternatives, including the impact in the overall budget. ENCORE will also provide mechanisms for the dwellers or owners to validate the project, either on-site with Augmented/Mixed Reality solutions, or on-line. Once the project is validated, ENCORE will automatically generate the work planning for the construction works, and once finalized, ENCORE will provide continuous monitoring of the energy consumption to ensure non-degradation of the renovation works. ENCORE will be validated in experimental facilities consisting of a baseline building and an experimental building that can be modified to measure the energy efficiency of the modification. Additionally, the pilot user owns several social buildings to renovate, where ENCORE can be validated in real life conditions.

NANONTUN3D will take advantage of the possibilities of Additive Manufacturing (AM) together with the development of a specially tailored Ti- based nano-aditived material to achieve dramatic improvements in structural parts of aero, space, mobility, and equipment sectors, reaching expected savings between 40% and 50% of material in critical applications. inherent benefits of AM will be kept (decrease in throughput times, tool-less production, high buy-to–fly-run ratios, etc.). By adding nano-particles (np) to metal matrixes, the whole life cycle of the NANOTUN3D material has been designed with AM processability in mind: safety and handling issues, processing in well-known AM technologies, postprocessing and eventual certification issues are dealt with, and innovative core-shell treatment of the nano-particles that suits the Ti matrix and produces Ti64-like powder ready to be AM processed. A whole Health, Safety and Environmental (HSE) management system will also be developed, as well as all the protocols to start qualification/certification of material and process.

SunCoChem will have an important impact in reduction of the dependence of the European Chemical Industry (ECI) on carbon feedstock by producing a competitive and integrated solution enabling the carbon-netural production of high valuable chemicals from solar energy, H20 and CO2. SunCoChem will provide a solution based on a competitive tandem photoelectrocatalytic reactor (TPER) to efficiently produce oxo-products from CO2, water and sunlight. This will be achieved by process intensification coupling a sun-driven carbon dioxide reduction to CO/water oxidation to O2 with C-C bond carbonylation reaction catalysed by novel multifunctional hybrid photoelectrocatalysts (PEcats) SunCoChem is focused on the production of 3 main oxo-products of interest for three important chemical industries in Europe: i) Glycolic Acid, used as polymers building block and of interest to AVANTIUM CHEMICALS BV; ii) Valeraldheyde, a flavor ingredient of interest to and produced by DOW CHEMICALS; and iii) LimoxalTM a fragrance ingredient of interest to and produced by IFF. The TPER will be demonstrated at a TRL5 scale of 1m2 and validated by a set of 3 case studies corresponding to the 3 selected products, representing real chemical industry needs from the 3 mentioned industrial partners. The sustainable and efficient technology for oxo-products production will be demonstrated by addressing the recycling CO2 flue gas and by-products from Dow Chemicals and IFF, with an improved chemical energy conversion efficiency (≥10%) and CO2 emissions reduction (≥50%). The advantages of the SunCoChem technology in terms of social and environment impact will be analyzed with respect to conventional production routes of the same target products. Maximum impact will be ensured through the involvement of the mentioned three industrial end users in the validation of the technology, a well-balanced dissemination, standardization, communication, stakeholders engagement and exploitation of the different results.

The AlchemiSSts project will demonstrate the applicability of the Safe by Design (SSbD) framework aiming at developing and implementing safer and more sustainable alternatives to surfactants, plasticizers, and flame retardants that, being present in daily life products pose a high risk for the human health and the environment, thus considered substances of very high concern (SVHC). To this end, up to seven case studies, accounting with the relevant actors in the value chain are proposed in the project, and they will serve as proof of concept to test the SSbD framework against within its different 5 steps. The general objective of the project will be achieved by addressing specific goals such as the development of the alternative substances itself, the compilation of robust and reliable evidence for a Proof of Concept of the SSbD framework, the development of a certification methodology promoting the implementation of the SSbD concept in the industrial network. Another key pillar of AlchemiSSts project relies on the implementation of integrated approaches and tools to support safety, sustainability and social assessment based on interoperable FAIR data and models. In addition, robust data on sustainability indicators and information for assessing the impact of the outcomes of the project towards a suite of zero pollution targets will be delivered for each case. For all these relevant aspects, AlchemiSSts will be assisted by stakeholders to ensure social acceptance and economic of the foreseen innovative advance materials.