DATAWiSE will develop and test building and building portfolio management tools, leveraging cross-sectoral lifecycle data on the basis of an open, secure, interoperable, and scalable framework. Utilizing cutting-edge artificial intelligence and advanced analytics, the methodology will integrate data from a variety of sources to provide a holistic understanding of building operations. DATAWiSE will design and implement a scalable data architecture that ensures data quality, privacy, interoperability, and sharing, and a Data Sharing Platform that will not only ensure interoperability and scalability but will also prioritize data sovereignty to secure data handling and preserve ownership control. DATAWiSE will develop: i) a Data-driven Building Performance Management (DBPM) toolkit which will harness Building Information Modeling (BIM) data in conjunction with advanced data mining techniques through a digital twin. ii) An AI-enhanced Lifecycle Data-driven Decision Support (LD2S) toolkit. This will serve as a versatile solution for well-informed decision-making across planning, renovation, and sustainability domains. Through these tools, the project will offer a suite of added-value services aimed at optimizing building management in various aspects: Electrical and Thermal Flexibility Management; AI-Powered Energy Forecasting and Optimization; Smart Sustainability & Comfort Balancing for Building Occupants; Adaptive Building Risk & Resilience Assessment; Circular Lifecycle Assessment; Predictive Maintenance; Integrated Sustainability Performance Management; Smart Readiness Assessment. Besides technological innovation, the project also incorporates a supportive market and policy framework designed to offer evidence-based pathways for widespread adoption and commercialization.

In order to tackle pressing societal issues, we must reconsider how we design and inhabit our neighbourhoods. The necessity of consistently including end users or local communities is sometimes overlooked in the planning, designing, and construction processes used today. However, combining community knowledge and initiatives can result in more liveable neighbourhoods that empower citizens and represent local needs and surroundings. Furthermore, the way public areas are constructed can have a big influence on how people interact with one another, what kinds of activities happen there, and how much trust the public has in their local government and democracy as a whole. The project seeks to rethink how neighborhoods are designed and experienced by emphasizing the importance of involving local communities in the planning, design, and construction processes. By incorporating community knowledge, more livable spaces can be created that meet local needs and empower residents. Public spaces are vital in fostering social interaction, trust in government, and democratic engagement. Equipping people with the tools to actively participate in co-designing these environments can strengthen social trust, enhance a sense of belonging, and boost community involvement. The "Sustainable Public Spaces through Inclusive Community Engagement (SPICE)" project aims to develop a participatory co-creation model for shaping neighborhoods. It will explore and test innovative methods to engage communities in co-designing and maintaining public spaces across diverse European neighborhoods. By promoting interdisciplinary collaboration, leveraging digital tools, and using sustainable construction practices, the project aims to address societal challenges, promote social inclusion, support democratic participation, and align with the European Green Deal and New European Bauhaus principles.

Fertilisation is key to feeding the growing world population, yet the most common fertilisation scheme based on conventional fertilisers poses threats to the environment (e.g. eutrophication caused by nutrient leaching) and sustainability of the EU food system (due to high dependence on fertiliser imports from third countries). Thus, among the key EU political priorities is to reduce by 20% the use of conventional fertilisers by 2030 and to decrease nutrient losses by 50%. A promising solution for this aim are alternative fertilisers produced from recovered nutrients from secondary raw materials (e.g. bio-waste, sewage sludge). However, their wide scale deployment is hindered by lack of awareness about alternative fertilisation, concerns regarding their technical viability and the disparity of legislations that creates a state of uncertainty. In this context, FER-PLAY is a comprehensive approach to gather, harmonise, select and complement the knowledge on alternative fertiliser value chains and diffuse it to promote the wide-scale production and application of alternative fertilisers with best environmental, social and economic performance as well as technical and regulatory viability. Thus, FER-PLAY employs a unique methodology for mapping the value chains, select the most promising ones and assess their impacts. FER-PLAY engages key stakeholders in co-creation of results and broadly disseminates them. The consortium gathers key players from the whole value chain: (1) alternative fertiliser producers from all the main types of secondary raw materials (producers of digestate- 183 members, of compost- 120 members and of struvite), (2) entities representing conventional (1.5M members), organic (100,000 members) and young (200,000 members) farmers, (3) a Pan-European network with +100 members representing public administrations, supported by (4) waste valorisation and agriculture research institutes, (5) market strategists and (6) communication experts.

The BIOS MATER aims to develop and demonstrate advanced bio-based construction products and building elements with tailored functional properties such as durability, fire resistance, water barriers, acoustic and thermal insulation, lightweight structure, mechanical strength, and antimicrobial features, ensuring safety and sustainability. At the core of the concept are the four Production routes which are built around four pillars. Specifically: Production route A will focus on the development of bio-based core product and sandwich structure for flooring applications, Production route B will focus on the development of bio-based wall panels and flooring tiles, Production route C will focus on the development of fiber reinforced bio-resin composite panels applied as exterior façade cladding panels and Production route D will focus on the development of biodegradable and plantable bio-based tiles from foams applied as drywalls panels. Moreover, the four pillars are: Pillar 1. Innovation in bio-based construction and building product development; Pillar 2. Health, safety, and environmental impact through Safe and Sustainable by Design (SSbD), Pillar 3. Circular economy integration and scalability and Pillar: 4 Driving market adoption of bio-based products through digital transparency, stakeholder engagement, and social acceptability. Key elements include life cycle assessments (LCA), circularity, and SSbD assessments. BIOS MATER will test and demonstrate the compatibility of these products with existing construction practices and regulatory frameworks at the controlled real-world application of a DEMOpark. The project also incorporates stakeholder engagement, training, and awareness programs, with 22 partners from 10 EU countries working together to achieve these goals across 7 work packages.

GreenFit is a collaborative project uniting research institutions, technology developers, agricultural practitioners, and field actors to tackle the barriers limiting farmers from adopting climate-smart practices. Through a combination of advanced technologies such as AI-powered decision support systems, IoT sensors, and XR-based training tools, GreenFit focuses on optimizing resource use, enhancing decision-making, and building resilience to climate change. The project also promotes value-chain partnerships and strengthens digital infrastructure, ensuring scalability and sustainability. Through the use of real-time tools, including the LLM-based AgriChatbot and a drone-in-a-box system for soil analysis and crop health monitoring, GreenFit empowers farmers with the practical, innovative solutions needed to transition toward sustainable practices. GreenFit focuses on capacity building and community-driven dissemination, communication, and exploitation, as through hands-on training, workshops, and stakeholder engagement, it empowers local communities to adopt and sustain climate-smart practices. The project’s capacity-building program and knowledge-sharing platforms ensure that farmers and rural stakeholders are actively involved in the development process. GreenFit's community-led approach enhances local ownership of solutions, driving sustained environmental and economic benefits.