Multi-scale quantification and modeling of aged nanostructured silicon-based composite anodes
Surface Oxidation of Nano-Silicon as a Method for Cycle Life Enhancement of Li-ion Active Materials
Ratynski, M., Hamankiewicz, B., Buchberger, D. A. et al., Molecules 2020, 25(18), 4093
Facile preparation of hierarchical 3D current collector for Li-ion anodes
Ratynski, M., Hamankiewicz, B., Czerwinski, A. Electrochimica Acta, 403 (2021)
Link: https://doi.org/10.1016/j.electacta.2021.139698
The role of coordination strength in solid polymer electrolytes: compositional dependence of transference numbers in the poly(ε-caprolactone)–poly(trimethylene carbonate) system
Eriksson, T., Mace, A., Mindemark, J., Brandell, D., Phys. Chem. Chem. Phys., 2021,23
Download: https://doi.org/10.1039/D1CP03929F
A cut finite-element method for fracture and contact problems in large-deformation solid mechanics
Poluektov, M., & Figiel, Ł. Computer Methods in Applied Mechanics and Engineering, 388 (2022)
Download: https://doi.org/10.1016/j.cma.2021.114234
Carbonyl-Containing Solid Polymer Electrolyte Host Materials: Conduction and Coordination in Polyketone, Polyester, and Polycarbonate Systems
Eriksson, T., Gudla, H., Manabe, Y., et al. Macromolecules 2022, 55 (2022)
Download: https://doi.org/10.1021/acs.macromol.2c01683
A Multiscale, Correlative, Air Free Workflow for the Analysis of Li Distribution in Batteries via ToF-SIMS
Kelly, S.T., White, R., Tordoff, B., et al. Microscopy and Microanalysis, Volume 28, Issue S1, August 2022
Download: https://doi.org/10.1017/S1431927622003841
Synchrotron Holotomography on Silicon-Based Anode Materials for Improved Lithium Ion Batteries
Chamasemani, F.F., Häusler, M., Vorauer, T., et al. Microscopy and Microanalysis, Volume 28, Issue S1, August 2022
Download: https://doi.org/10.1017/S1431927622001672
Impact of solid-electrolyte interphase reformation on capacity loss in silicon-based lithium-ion batteries
Vorauer, T. Schöggl, J., Sanadhyan, S.G., et al. Communications Materials, 4, 44 (2023)
Download: https://doi.org/10.1038/s43246-023-00368-1
Uncovering the impact of coordination chemistry on cation transport in polymer electrolytes
Jonas Mindemark
European Polymer Congress
26.06.-01.07.2022
Prague, Czech Republic
EPF22-Mindemark.pdf
Adobe Acrobat Document
831.5 KB
Elucidating the Electrochemical Stability of Polymer Electrolytes
Guiomar Hernández, Isabell L. Johansson, Alma Mathew, Christofer Sångeland, Daniel Brandell, Jonas Mindemark
17th International Symposium on Polymer Electrolytes (ISPE-17)
02.-07.10.2022
Niagara-on-the-Lake, Ontario, Canada
ISPE-17_Hernandez.pdf
Adobe Acrobat Document
281.9 KB
Gel Polymer Electrolytes Based on Methacrylate End-Capped Poly(trimethylene) Carbonate Oligomers for Lithium Batteries
Vidyanand Vijayakumar, Daniel Brandell, Jonas Mindemark
European Polymer Congress
26.06.-01.07.2022
Prague, Czech Republic
EPF22-Vijayakumar.pdf
Adobe Acrobat Document
2.6 MB
To hop or not to hop: How to accurately describe the diversity of ion transport modes in solid polymer electrolytes
Jonas Mindemark, Harish Gudla, Anne Hockmann
17th International Symposium on Polymer Electrolytes (ISPE-17)
02.-07.10.2022
Niagara-on-the-Lake, Ontario, Canada
ISPE-17_Mindemark.pdf
Adobe Acrobat Document
317.7 KB
Ageing of nanostructured silicon-based composite anodes: Morphology changes and inhomogeneous lithiation
Brunner, R. (2020)
Read: https://go.nature.com/3lWmRuC
Improving the Design of Anode Materials in Lithium Ion Batteries
Interview with R. Brunner on the ZEISS Blog
Read: https://blogs.zeiss.com/microscopy/en/fesem-anode-materials/
Generation I of electrolyte (high-liquid)
The 1st generation of electrolyte will be a high liquid gelified electrolyte containing linear polycarbonates. The electrolyte composition will be based on state-of-the-art from the SINTBAT project.
ECO2LIB D2.2.pdf
Adobe Acrobat Document
101.2 KB
50 Gen1 CoinPower cells with 10 % improved capacity manufactured
Production of 50 Gen1 CoinPower cells. The produced cells should achieve an improved capacity of 10% compared to state of the art CoinPower cells.
ECO2LIB D3.3.pdf
Adobe Acrobat Document
360.5 KB
Comparative Study on existing LIB recycling technologies
Overview of industrially available recycling technologies, providing a benchmark for the proposed recycling technology of ECO²LIB project. Furthermore, overview of recently developed recycling technologies from literature and patent research. Finally, comprehensive evaluation of the various processes in view of material efficiency, investment, capacity, general economic and environmental performance, etc.
ECO2LIB D5.1.pdf
Adobe Acrobat Document
2.1 MB
First Report on the characterization of electrolytes
Description of the development of the electrolyte system for the project, including conductivity, electrochemical stability, diffusivity, rheological properties, interfacial stability for Generation I of the electrolytes.
ECO2LIB D6.4.pdf
Adobe Acrobat Document
528.4 KB
Plan for exploitation and dissemination
Overview of the activities planned for exploitation and dissemination of project results.
ECO2LIB D9.3.pdf
Adobe Acrobat Document
227.7 KB
Benchmarking Results
For the comparison of the ECO2LIB cells with worldwide competition, the respective test results will be shown and compared.
ECO2LIB D4.2.pdf
Adobe Acrobat Document
794.0 KB
Requirements specification
The specification of the requirements for the LIB cells especially for stationary applications will be described and fixed as a measure for the project success.
ECO2LIB D4.1.pdf
Adobe Acrobat Document
1'011.9 KB
First delivery of input and validation data on electrochemical testing of components and cells
Summary of the first set of electrochemical data related to electrochemical properties of Si-based electrodes. These include i.a. specific capacity, potential profiles, SEI layer resistance, CT resistance, lithium diffusion coefficient, electric conductivity.
ECO2LIB D6.1.pdf
Adobe Acrobat Document
2.2 MB
Project identity, website and social media channels
Report on the ECO²LIB online and digital communication activities incl. Logo, website, social media, etc.
ECO2LIB D9.1.pdf
Adobe Acrobat Document
1.0 MB
1st Project Newsletter
1st ECO2LIB Newsletter.pdf
Adobe Acrobat Document
216.1 KB
3rd Project Newsletter
3rd ECO2LIB Newsletter.pdf
Adobe Acrobat Document
458.4 KB
5th Project Newsletter
5th ECO2LIB Newsletter.pdf
Adobe Acrobat Document
596.6 KB
7th Project Newsletter
7th ECO2LIB Newsletter.pdf
Adobe Acrobat Document
508.3 KB
2nd Project Newsletter
2nd ECO2LIB Newsletter.pdf
Adobe Acrobat Document
431.2 KB
4th Project Newsletter
4th ECO2LIB Newsletter.pdf
Adobe Acrobat Document
467.5 KB
6th Project Newsletter
6th ECO2LIB Newsletter.pdf
Adobe Acrobat Document
633.2 KB
8th Project Newsletter
8th ECO2LIB Newsletter.pdf
Adobe Acrobat Document
659.1 KB
