GO-Forward aims to develop a novel methodological approach to make more accurate pre-drilling predictions of geothermal reservoir properties and thus reduce the mining risk. Key to the GO-Forward approach is to simulate geological processes for pre-drill assessment of reservoir structure and properties, calibrated to geological or geophysical data, rather than extrapolating the properties from those data with geostatistical methods. To this end, GO-Forward focuses on extending and further developing, testing and demonstrating the added value of forward modelling methods originally developed for hydrocarbon exploration, including stratigraphic forward modelling (SFM), diagenesis forward modelling (DFM) and fracture network forward modelling (FFM), to be used for exploration in different geothermal settings of high relevance for Europe. First, the developed approaches will be tested and calibrated in areas with abundant subsurface information and production data, to prove conceptually the applicability of the methods and reproducibility of the results, to optimise and de-risk geothermal exploration. Calibrated model approaches are subsequently applied in areas with limited data availability to demonstrate their capability to increase pre-drill Probability of Success (POS). To support the workflow and further reduce exploration costs, GO-Forward advances ML-based and computational methods to enhance (existing) (sub)surface information for calibration, uncertainty quantification and data assimilation, and (upscaling) routines for flow simulation, DNSH, and techno-economic performance assessment for POS and Value of Information (VOI). In addition, GO-Forward addresses public awareness of geothermal developments already at the early stages of exploration. By including novel approaches to citizen engagement and stakeholder dialogue, we aim to increase the societal readiness level of geothermal exploration as the first step of geothermal developments.

Natural hazards, such as extreme weather events, are exacerbated by climate change. As a result, emergency responses are becoming more protracted, expensive, frequent, and stretching limited available resources. This is especially apparent in rapidly warming regions. MedEWSa addresses these challenges by providing novel solutions to ensure timely, precise, and actionable impact and finance forecasting, and early warning systems (EWS) that support the rapid deployment of first responders to vulnerable areas. Specifically, MedEWSa will deliver a sophisticated, comprehensive, and innovative pan-European–Mediterranean–African solution comprising a range of complementary services. Building on existing tools MedEWSa will develop a fully integrated impact-based multi-hazard EWS. This call contained five expected outcomes, all of which will be specifically addressed by MedEWSa. Led by WMO, MedEWSa will be an exemplar of the UN Secretary General’s March 2022 call to ensure that everyone on Earth is protected from extreme weather and climate-related hazards by EWS within the next five years. Through eight carefully selected pilot sites (areas in Europe, the southern Mediterranean, and Africa with a history of being impacted by natural hazards and extreme events with cascading effects), four twins will be created: ● Twin #1: Greece (Attica) – Ethiopia (National Parks): wildfires and extreme weather events (droughts, wind) ● Twin #2: Italy (Venice) – Egypt (Alexandria / Nile Delta): coastal floods and storm surges ● Twin #3: Slovakia (Kosice) – Georgia (Tbilisi): floods and landslides ● Twin #4: Spain (Catalonia) – Sweden (countrywide): heatwaves, droughts and wildfires. The twins will bridge areas with different climatic/physiographic conditions, yet subject to similar hazards, and are well positioned to deliver long-term bi-directional knowledge transfer. They will demonstrate the transferability and versatility of the tools developed in MedEWSa.

We aim to contribute to the European Green Deal, the UN Sustainable Development Goals and the Horizon Europe objectives through the development of a Geological Service for Europe, which focuses on the planet itself: the earth beneath our feet. The subsurface holds indispensable resources for European industries and opportunities to decarbonise our economy, but also requires careful management to preserve a healthy and safe living environment for Europe’s citizens. Structurally addressing the EU dimension in geological services is needed because the scale of many societally and economically relevant geological features exceeds that of individual countries. Addressing transnational and continental-scale problems requires innovation, standardisation, harmonisation as well as a shared vision. We aim to build the Geological Service for Europe based on Europe’s best practices and implement the Service with the backing of the Union. Existing geological surveys, the national custodians of geological information, have amassed huge legacies of data and information that are difficult to merge. This project will continue the harmonisation and standardisation effort initiated in earlier projects. We aim to create joint services that can support acceleration of the energy and climate transitions, as well as a larger critical mass of intra-European cooperation through convergence of our research agendas, as key steps to increase the amount and quality of results we are aiming for. A common thread in this project is innovation in ways in which subsurface information is conceptualised, organised, visualised, delivered and translated to the needs of a wide range of audiences, and the methodologies to achieve this. Building on the groundwork laid in the GeoERA program, we will scale up and out, not only scientifically, but also in involving national stakeholders in the network, in order to create support and eventually obtain a mandate for a European Service on a permanent basis.

Planet Earth faces unprecedented environmental changes that will affect all members of society. Arctic climate warming is more than twice the global rate and unpredictable extreme events cause major impacts on ecosystems and people. However, the Arctic atmospheric circulation causes extreme events and societal damage beyond the Arctic which need international research and monitoring to understand and predict. Furthermore, attitudes need to be changed throughout the world through outreach while the next generation needs to be equipped to live in a different world. INTERACT III innovates a pan-arctic network of 86 research stations in 16 northern countries to provide a fully integrated, advanced infrastructure now able to meaningfully address major societal challenges and provide services for 155 global and regional networks. Furthermore, the global reputation of INTERACT has attracted world-leading partners and enterprises to participate in reducing the impacts of hazardous change while maximizing the opportunities arising from new technologies. Specifically, INTERACT III provides comprehensive coordination of 64 partners and 86 research stations. The station managers design best practices to ensure excellent research, monitoring, education and outreach. INTERACT III builds on an extremely successful transnational access program that has already populated the Arctic with 900 researchers to further provide excellent science while reducing the environmental footprints of researchers through improving remote and virtual access. The access transnationality ensures new collaborations, innovative science and science diplomacy at a time of heightened geopolitical tensions. Station managers, transnational access and joint research activities cooperate to address major societal challenges in a fully integrated infrastructure while their data and understanding are made globally available through exceptional outreach and education and policy briefings to decision makers.

According to the EU’s Climate Adaptation Strategy (COM(2021) 82), “improving knowledge and managing uncertainty” is key for realising the vision of a climate neutral and climate-resilient Union, as “Climate change is having such a pervasive impact that our response to it must be systemic”. Thus, there is an urgent need for an integrated approach for an enhanced understanding of the interaction, complementarity and trade-offs between adaptation and mitigation measures, especially regarding the expected increase in region-al mean temperature, precipitation and changing soil moisture (IPCC AR6 WG I). Furthermore, this under-standing and knowledge needs to be provided to a broad audience to support local authorities in EU partner countries in developing regional programmes. KNOWING aims to develop a modelling framework to help understand and quantify the interactions between impacts and risks of climate change, mitigation pathways and adaptation strategies. The framework will be used to assess thAdvancing climate science and further broadening and deepening the knowledge base is essential to inform the societal transition towards a climate neutral and climate resilient society by 2050, as well as towards a more ambitious greenhouse gas reduction target by 2030. There is a need for research that furthers our understanding of past, present and expected future changes in climate and its implications on ecosystems and society, closing knowledge gaps, and develops the tools that support policy coherence and the implementation of effective mitigation and adaptation solutions. Currently, there is a lack of knowledge of the Earth system and the ability to predict and project its changes under different natural and socio-economic drivers, especially regarding complex interrelations, rebound effects and behavioural aspects. Therefore, a holistic, system-aware and behaviour centred approach is needed to identify and implement realistic and effective climate mitigation pathways.