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Website: {{Template:Viewer/Link|page=|url=https://www.inerrant-batteries.eu|label=www.inerrant-batteries.eu}} | Website: {{Template:Viewer/Link|page=|url=https://www.inerrant-batteries.eu|label=www.inerrant-batteries.eu}} | ||
Cordis: | Cordis: https://cordis.europa.eu/project/id/101147457 | ||
EU-Call: HORIZON-CL5-2023-D2-02 | EU-Call: HORIZON-CL5-2023-D2-02 | ||
Revision as of 22:48, 16 January 2025
| INERRANT [OSWd115cd75912148f9b036c632eae1b5f9] | |
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| ID | OSWd115cd75912148f9b036c632eae1b5f9 |
| UUID | d115cd75-9121-48f9-b036-c632eae1b5f9 |
| Label | INERRANT |
| Machine compatible name | INNERANT |
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| Statements (outgoing) | |
| Statements (incoming) | |
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| Keywords | |
Description
An EU Horizon Europe research project and part of the Battery2030+ initiative, aiming to optimise the key materials and processes establishing a credible method for producing safer Gen 3 LIBs.
| Item | |
|---|---|
| Type(s)/Category(s) | Project |
| Project | |
|---|---|
| Type | House project |
| Grantor | |
| Funding call | |
| Grant ID | |
| Start | 2024-05-15 |
| End | 2027-05-14 |
| Budget | 0.0e+0 |
| OU | |
| Project manager | Spyros Yannopoulos |
| Member | |
Abstract
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.
Explanation of the Name of the project
INERRANT stems from the title of the project: "Integrating Novel matERials with scalable processes for safer and recyclAble Li-ioN baTteries"
Topic of the project
INERRANT is committed to pushing the boundaries of current LIB technologies by developing innovative material combinations, advanced electrolyte formulations and eco-friendly recycling methods that prioritise safety and recyclability. This holistic approach targets the entire battery lifecycle, from design and manufacturing to end-of-life recycling. The project leverages cutting-edge science and technology to build the foundation for safer energy storage solutions, paving the way for a future where mobility is both eco-friendly and secure.
Keywords
Energy storage; Novel graphite and laser-grown graphene/Si-SiOx anodes; Ni-rich and LMFP cathodes; separators; shear thickening electrolytes; fast charging; pilot lines; Gigafactory-scale; LIBs for e-mobility
Project Coordinator
Professor Spyros Yannopoulos, Foundation for Research and Technology Hellas & University of Patras
Consortium Members
- Foundation for Research and Technology Hellas
- Pleione Energy
- Jan Evangelista Purkyne University in Usti nad Labem
- University College Dublin
- Fraunhofer Institute for Silicate Research
- University of Würzburg
- IBG Česko
- nanoSPACE Technology
- Keysight Technologies
- Verkor
- European Research and Project Office
Website and important links
Website: www.inerrant-batteries.eu
Cordis: https://cordis.europa.eu/project/id/101147457
EU-Call: HORIZON-CL5-2023-D2-02
LinkedIn: https://www.linkedin.com/company/inerrant-batteries/
Twitter/X:
YouTube:
Other:
Goals of the project
- Innovative (nano) material combinations for anodes and cathodes
- Smart separators able to protect against battery flaws
- Stimuli responsive electrolyte formulations designed for rapid reactions against external disturbances to mitigate cathode degradation
- Novel sustainable recycling processes to improve the purity of recovered materials
Results
Lorem Ipsum
Budget
4 433 848.75
Duration (and maybe Extension)
36 months
Publications
Lorem Ipsum
Patents
jsondata
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| project_type | "house_project" | |||||
| project_status | "Item:OSW55a9a9bda7b248759e48ae2e3ed6df1d" | |||||
| funding_call | "" | |||||
| funder | "" | |||||
| funding | "" | |||||
| funding_name | "" | |||||
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| member |
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| start_date | "2024-05-15" | |||||
| end_date | "2027-05-14" | |||||
| total_budget | 0 | |||||
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| proposal | "" | |||||
| abstract | "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." | |||||
| uuid | "d115cd75-9121-48f9-b036-c632eae1b5f9" | |||||
| label |
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| description |
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| name | "INNERANT" | |||||
| image | "File:OSW600da968c4a04846b2b3f01628c10c1e.png" |