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Property "HasImage" (as page type) with input value "https://upload.wikimedia.org/wikipedia/commons/b/b9/Logo_INSA_Lyon_%282014%29.svg" contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasAbstract" (as page type) with input value "HYDRA aims to develop the next generation of commercially viable Li-ion battery cells based on sustainable materials and manufacturing processes. Within the roadmap for future battery development, these Li-ion battery cells are referred to as generation 3b. They aim to increase the energy density of the cells by developing new materials, while also reducing the critical raw materials (CRM) content by more than 85%. To achieve this goal, high-capacity silicon is blended together with graphite in the anode and cobalt-free lithium nickel manganese oxide (LNMO) and lithium iron phosphate (LFP) materials are used in the cathode." contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasAbstract" (as page type) with input value "INERRANT aims to drive genuine advancements for safe-and-sustainable-by-design materials, and eco-friendly processes, to ensure the economical and widespread utilization of safer LIBs tailored for the expanding electromobility applications in our modern society. To realize this, INERRANT is formulating a holistic approach to enhance safety performance, extend cyclability and operational lifespan, and improve fast charging, all while maintaining cost-effectiveness, energy, and power density, and avoiding dependence on Critical Raw Materials. The pivotal S&T challenges encompass: development of functional materials, design sustainable recycling processes and understanding of pertinent interfacial phenomena and degradation mechanisms. The project addresses current challenges for LIBs components related to (i) novel (nano)materials combinations for anodes and cathodes; (ii) smart-functioning separators; (iii) stimuli responsive electrolyte formulations; (iv) novel sustainable recycling processes to improve the purity of recovered materials. Novel electrochemical characterization methods and operando spectroscopies, both at the materials and component level, will be utilized. This includes the establishment of a metrological framework for traceable calibrations and the integration of machine learning methodologies for swift and early LIB cell aging predictions. Adopting fabrication methods that are inherently scalable, built upon existing pilot lines and proven safety testing, will facilitate a swift progression to Gigafactory-relevant scales. INERRANT will present a compelling business case and clear exploitation strategy, rooted in the consortium’s strategic insight, guaranteeing effective technology commercialization. This approach will support the economical and eco-friendly production of LIB cells and systems, tailored for e-mobility applications. INERRANT comprises a consortium of 11 partners from the European Commission and one associated partner from the USA." contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasAbstract" (as page type) with input value "Li-ion batteries play a crucial role in Europe’s energy transition, yet production dominance lies with China, Korea, and Japan. To counter this dependency, Europe plans to establish 25 new gigafactories amounting to EUR 35 billion by 2030. However, defects are anticipated to occur at rates ranging from 15 % to 30 % during the initial ramp-up phase. In response, the EU-funded BATTwin project aims to mitigate defect rates in battery production by implementing a comprehensive approach. This involves integrating a multi-sensor data acquisition and management layer, a Digital Battery Passport data model, process-level digital twins, and system-level digital twins to facilitate Zero-Defect Manufacturing. The platform incorporates user-centric, goal-driven digital twin workflows to guide users in system design and control." contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasWebsite" (as page type) with input value "https://en.wikipedia.org/wiki/%C3%89cole_Polytechnique_F%C3%A9d%C3%A9rale_de_Lausanne" contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasAbstract" (as page type) with input value "While battery performance and safety have become increasingly urgent, current battery management systems fall short. In this context, the EU-funded NEMO project seeks to redefine the state-of-the-art in battery management by harnessing advanced physics-based and data-driven models, complemented by state estimation techniques. The project is set to introduce innovative software and hardware solutions, offering a powerful tool to enhance battery performance and longevity in our ever-evolving energy landscape. Specifically, it will use a spectrum of sensors capturing battery performance information as well as specialised electrochemical impedance spectroscopy (EIS) sensors. The solutions will pave the way for new performance, lifespan, and safety models." contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasMainUnitSymbol" (as page type) with input value "€/[1" contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasAbstract" (as page type) with input value "Battery innovation is key in the evolution of new energy production and transport technologies. However, progress in the field is currently impeded by insufficient understanding of atomic-level processes occurring within the interfaces and interphases of batteries. The EU-funded OPINCHARGE project aims to develop a set of operando nanoanalytical techniques to understand such processes in unprecedented detail. The consortium, comprising 10 organisations from 7 countries, will pioneer different chemical and physical techniques. They will also integrate AI/machine learning to enhance data acquisition and analysis. Strong focus will be placed on data sharing – a critical aspect of the Battery Interface Genome – Materials Acceleration Platform (BIG-MAP)." contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasImage" (as page type) with input value "https://upload.wikimedia.org/wikipedia/commons/1/1c/Coll%C3%A8ge_de_France_logo.svg" contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasWebsite" (as page type) with input value "https://en.wikipedia.org/wiki/University_of_M%C3%BCnster" contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasAbstract" (as page type) with input value "With the increasing reliance on Li-ion batteries (LIBs) to power our devices and facilitate the transition to renewable energy sources, the pressing problem of their limited lifespan and environmental impact looms large. LIBs degrade over time, and their production generates significant carbon emissions. In this context, the EU-funded SALAMANDER project offers a groundbreaking solution to these challenges. Specifically, it aims to embed advanced sensors and self-healing capabilities within LIBs, creating smart batteries that can autonomously detect and repair damage. This innovative approach not only promises longer-lasting, more reliable batteries but also aligns with the goal of a sustainable European battery value chain and a greener future." contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasAbstract" (as page type) with input value "Focusing on electromobility applications, especially electric cars, buses and trucks, the EU-funded IntelLiGent project will develop and demonstrate European generation 3b high voltage lithium-ion batteries with increased energy density, faster charging and longer cycle life. IntelLiGent will combine Co-free high voltage cathodes with high-capacity silicon-graphite anodes to increase energy- and power- densities. As an evolution of existing chemistries, the manufacturing processes are compatible with those currently used commercially, and so the project goal is to provide a direct boost to the European battery value chain by enabling world-leading battery technologies using already optimised manufacturing methods. Further, the project will focus on materials production and processing routes which substantially reduce the manufacturing cost and environmental footprint." contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasWebsite" (as page type) with input value "https://en.wikipedia.org/wiki/Coll%C3%A8ge_de_France" contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasAbstract" (as page type) with input value "PHOENIX aims to develop battery cells with integrated sensors (mechanical, enhanced impedance spectroscopy, temperature, gas, reference electrode) and self-healing functionalities (magnetically activated polymers, thermally activated polymers, metallic organic frameworks coated separator, core-shell NMC composites). Tailor made triggering devices to activate self-healing mechanisms will be developed, prototyped and demonstrated in Generation 3b and 4a Li-Ion batteries. A Battery Management System (BMS), capable of detecting defective operations and of triggering self-healing functionalities will be developed with in-line communication. The degradation detection and quality, reliability and life will be tested through dedicated profiles (fast charging, extreme temperatures, calendar life). The novel batteries’ manufacturing will be studied from a recycling and mass production point of view." contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasAbstract" (as page type) with input value "The Battery Modelling Toolbox (BattMo) is a resource for continuum modelling of electrochemical devices in MATLAB and Julia. The initial development features a pseudo X-dimensional (PXD) framework for the Doyle-Fuller-Newman model of lithium-ion battery cells. However, the development plan for BattMo includes extensions to other battery chemistries (e.g. metal-air) and eventually hydrogen systems (i.e. electrolyzers and fuel cells)." contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasImage" (as page type) with input value "https://upload.wikimedia.org/wikipedia/commons/2/2a/Danmarks_Tekniske_Universitet_%28logo%29.svg" contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasAbstract" (as page type) with input value "REVITALISE delivers a holistic solution for green, low-cost, and low environmental impact recycling of NMC (Hi-Ni), LFP and Na-Ion batteries, representing 85% of battery waste streams up to 2025. REVITALISE develops low-cost and green processes to recover a full range of battery materials, including NMC, LFP, Al, Cu, Li, graphite, fluorides, phosphates and plastics. Overall recycling rates of 91%+ will be proven at TRL4 for waste processed from post-production scrap and end-of-life battery black mass. REVITALISE will develop innovative pre-treatment technologies based on electrohydraulic fragmentation, ultrasonication and magnetic, and electrostatic separation that will achieve very high levels of material stream purity. This will enable commercially viable recycling of low-value parts. The approach will enable direct recycling of 40% of the cathode and anode active parts, with direct characterisation of the lithiation (or sodiation) being developed that will be used as a basis of a smart-reformation approach for reclaimed active materials. The remaining 60% being suitable for hydrometallurgical recycling based on leaching with green organic acids from food waste, such as vitamin C (ascorbates), vinegar (acetate) and citric acid (citrates) and inorganic acids produced from industrial wastes. A further innovation is the development of water remediation with Li recovery from all wastewater streams generated, through the implementation of polymeric nanocomposite membrane separation with direct Li recycling for Li in water concentrations down to 0.6mg/L. The recycled parts will be assessed for (closed-loop) battery and other secondary applications for precursors and semi-products by industrial partners Verkor and Hydro, through reformulation and upcycling of battery materials and validation of remanufactured batteries. An optimised process flow will be determined to achieve commercially viable recycling with maximised recovery rates and minimal environmental impact." contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasImage" (as page type) with input value "https://upload.wikimedia.org/wikipedia/commons/8/83/IT-Universit%C3%A4t_Kopenhagen_Logo.svg" contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.

Property "HasWebsite" (as page type) with input value "https://en.wikipedia.org/wiki/Forschungszentrum_J%C3%BClich" contains invalid characters or is incomplete and therefore can cause unexpected results during a query or annotation process.