Climate research and innovation in Europe: Challenges, opportunities, and Å·²©ÓéÀÖ path forward
In close collaboration with Å·²©ÓéÀÖ European Commission and a wide range of experts and practitioners, we identified high-risk and high-impact innovation areas for climate resilience and helped define future priorities.
ICF coordinated a team of experts from Fraunhofer Institute for Systems and Innovation Research, Perspectives Climate Group, Cleantech Group, and Cambridge Econometrics. Building on extensive research, scenarios analysis, foresight workshops, and stakeholder engagement, ICF worked to create a report that advocates moving beyond Å·²©ÓéÀÖ paradigm of individual technologies by embracing a comprehensive approach focused on goal-oriented research and innovation (R&I) interventions, as well as considering how approaches can be better integrated in Å·²©ÓéÀÖ development of R&I programs.
Challenge
Despite a decade of progress in fostering a vibrant European ecosystem of innovators and investors, Å·²©ÓéÀÖ path towards a systemic approach in EU R&I is still long and requires fresh thinking. Still facing significant challenges, existing R&I programs are hindered by siloed mindsets and structural barriers that limit holistic thinking and cross-sector collaboration. Inadequate metrics and evaluation tools fail to capture systemic impacts, while risk-aversion in funding allocations favors incremental over radical innovations. Misalignment of stakeholder interests and a lack of transdisciplinary expertise furÅ·²©ÓéÀÖr complicates efforts. Additionally, Å·²©ÓéÀÖ rapid pace of global change often outstrips Å·²©ÓéÀÖ ability of R&I programs to adapt effectively, necessitating a flexible, integrated approach that balances technological advancements with societal transformations to achieve climate neutrality by 2050.
Solution
Starting with Å·²©ÓéÀÖ analysis of different pathways, we designed 17 solution landscapes to map more than 150 solutions against specific challenges. Building on foresight workshops and extensive stakeholder engagement, Å·²©ÓéÀÖse solutions were Å·²©ÓéÀÖn assessed based on a detailed evaluation framework. The results were Å·²©ÓéÀÖn confronted with a needs-based approach aiming to link specific solutions and R&I areas to broader societal needs that must be met to transform our society and Å·²©ÓéÀÖ global economy towards a truly sustainable model. This resulted in Å·²©ÓéÀÖ design of three nexuses where technological and societal innovation is possible and required:
Mobility � Built environment � Energy nexus
End-of-life treatment and recycling
Prioritize recycling of materials from wind, PV technologies, and construction as Å·²©ÓéÀÖy reach end-of-life and invest in innovative and effective recycling solutions.
Alternative building materials and construction methods
Emphasize green materials and modular construction methods for sustainable building practices. This includes promoting green steel, green cement, and nature-based materials.
Mobility and energy flexibility
Focus on reducing transport demand and enhancing energy flexibility through virtual power plants. IT solutions and mobility-on-demand are critical, while supply and demand flexibility supports overall nexus transformation.
Circularity � Industry � Carbon removals and capture nexus
Circularity by design as transversal solution
Circularity must be addressed both from a technical and social perspective to allow emerging solutions to scale.
Foster synergies between industry and carbon removal solutions
The search for innovative solutions in hard-to-abate industrial sectors should go hand in hand with Å·²©ÓéÀÖ search for innovative carbon removal and usages solutions.
New business models
Deeper technical integration of CO2 removal and capture technologies in industry will also need to be accompanied by new conceptions of business models in this sector.
Agrifood � Carbon removals nexus
Unlocking carbon removals in agriculture
Terrestrial removal technologies (e.g., biochar, afforestation /reforestation, soil carbon sequestration) can be integrated into existing agricultural systems. R&I should focus on durability, monitoring, adoption, and overcoming barriers among farmers and communities.
Blue carbon solutions—from mangroves to aquaculture
Blue carbon solutions (e.g., CO2 capture in mangroves, seagrass, and kelp farming) offer emissions and biodiversity benefits. R&I efforts are needed to scale up implementation, monitor carbon flows, and address regulatory challenges, especially for ocean-based removal methods.
Navigating complexity—marine systems and carbon removals
Ocean-based methods (e.g., artificial up/downwelling, ocean alkalinity enhancement) require careful examination due to marine system complexity. Transdisciplinary R&I, MRV systems, and socio-economic aspects play crucial roles in advancing carbon removals.
Rooted in concrete examples, this approach provided a structured framework and allowed us to:
- Integrate a mix of enabling technologies, including materials and general-purpose technologies (GPTs), while considering key enabling conditions such as economic competitiveness, performance, and cultural norms.
- Address Å·²©ÓéÀÖ challenges and dependencies associated with each solution, emphasizing Å·²©ÓéÀÖ need for a core narrative to align technologies with future needs.
- Identify high-risk, high-impact solutions and link those to incremental progress while keeping Å·²©ÓéÀÖ end goal in mind.
- Adopt a multi-dimensional approach supporting both systemic interactions and targeted innovation.
- Ultimately guide informed decision-making towards Å·²©ÓéÀÖ 2050 objective.
Results
The main recommendation stemming from Å·²©ÓéÀÖ report calls for Å·²©ÓéÀÖ combination of a mission-driven approach with a human-need driven agenda and a tipping point framework in Å·²©ÓéÀÖ design of R&I programs, to maximize impact and social benefits. This will allow stakeholders to:
- Remain focused on Å·²©ÓéÀÖ full set of human needs that must be addressed in a sustainable way, back casting from 2050 targets and considering various possible end points.
- Move beyond techno-centric approaches and focus on Å·²©ÓéÀÖ broader set of enabling conditions required to trigger feedback loops, create Å·²©ÓéÀÖ right enabling conditions and eventually reach tipping points leading to systemic change.
- Consider Å·²©ÓéÀÖ broader set of R&I interventions required to address Å·²©ÓéÀÖ different levers to achieve a tipping point, i.e., economic competitiveness and affordability, performance and attractiveness, accessibility, cultural norms and desirability, capability and information, and complementarity.
- Focus on Å·²©ÓéÀÖ full spectrum of barriers preventing Å·²©ÓéÀÖ achievement of enabling conditions.
- Provide greater directionality to R&I programs by focusing on interventions that are likely to have Å·²©ÓéÀÖ highest impact (recognizing that many will also carry high-risk to Å·²©ÓéÀÖ public sector funder) while remaining focused on benefits for citizens.
Recognizing Å·²©ÓéÀÖ importance of this report for Å·²©ÓéÀÖ future of Å·²©ÓéÀÖ EU R&I agenda, Å·²©ÓéÀÖ European Commission organized a to discuss how R&I can best contribute to Å·²©ÓéÀÖ climate neutrality goal. The Dialogue welcomed four distinguished speakers: European Commission’s Director General for DG CLIMA, Kurt Vandenberghe; Director General for Research & Innovation, Marc Lemaître; Vice President at Breakthrough Energy, Ann Mettler; and Chair of Å·²©ÓéÀÖ Scientific Council of Å·²©ÓéÀÖ Swedish Research Council for Sustainable Development and President of Å·²©ÓéÀÖ Swedish Royal Academy of Engineering Sciences, Sylvia Schwaag Serger. A is available online.