DEVELOPMENT OF OPERANDO TECHNIQUES AND MULTISCALE MODELLING TO FACE THE ZERO-EXCESS SOLID-STATE BATTERY CHALLENGE

Climate, Energy & MobilityHORIZON-RIAID: 101103834
EC Contribution
€44,164
Consortium Size
12 orgs
Start Year
2023
Summary

Green, high-performing and safe batteries based on abundant materials are a key element in the transition to a carbon-neutral future. However, to accelerate their development, a deep understanding of the complex electro-chemo-mechanical processes within the battery is required, which is only accessible through advanced experimental and computational methods. Zero-excess solid-state batteries, where the anode is formed in situ, have emerged as a promising new generation of environmentally friendly batteries with high energy density, improved safety and higher cost-efficiency, but only after solutions for non-uniform anode formation were found.In OPERA, seven leading research institutions, two synchrotron radiation facilities, a small-medium sized enterprise and a large technological company, all from complementary research fields such as batteries, surface and material science, and multiscale modelling, propose a unique strategy to face the current challenges of this technology. OPERA relies on the development of novel operando experimental techniques at the ESRF, ALBA and DESY synchrotrons and at the lab-scale, providing complementary information on multiaxial stress fields, chemical composition, nucleation and growth kinetics, structural defect formation and degradation of well-defined model cells with a resolution down to the atomic scale. The new insights and collected multiparameter data will be incorporated into a novel multiscale modelling approach supported by machine learning algorithms. This will ultimately lead to a conceptual understanding of the in-situ anode formation and, based on this, innovative improvement approaches to enable this type of energy storage technology, which will be an important step towards increasing the global competitiveness, resilience and independence of the EU.

Consortium (12)

Project Results (12)

Source: CORDIS, the EU research results database.

Publications (4)
Identifying Problematic Phase Transformations in Pb Foil Anodes for Sodium-Ion Batteries
Journal of The Electrochemical Society· 2024DOI
Jia Zhang, Tianye Zheng, Xiaoyang Guo, Hung Quoc Nguyen, Ka-wai Eric Cheng, Kwok-Ho Lam, Daniel Rettenwander, Wei Jin, Steven T. Boles
Operando Spatial and Temporal Tracking of Axial Stresses and Interfaces in Solid‐state Batteries
Small· 2024DOI
Simon Mičky, Erik Šimon, Juraj Todt, Karol Végsö, Peter Nádaždy, Peter Krížik, Eva Majková, Jozef Keckes, Ju Li, Peter Siffalovic
Understanding the origin of lithium dendrite branching in Li6.5La3Zr1.5Ta0.5O12 solid-state electrolyte via microscopy measurements
Nature Communications· 2024DOI
Can Yildirim, Florian Flatscher, Steffen Ganschow, Alice Lassnig, Christoph Gammer, Juraj Todt, Jozef Keckes, Daniel Rettenwander
2023 Roadmap on molecular modelling of electrochemical energy materials
Journal of Physics: Energy· 2023DOI
Chao Zhang, Jun Cheng, Yiming Chen, Maria K Y Chan, Qiong Cai, Rodrigo P Carvalho, Cleber F N Marchiori, Daniel Brandell, C Moyses Araujo, Ming Chen, Xiangyu Ji, Guang Feng, Kateryna Goloviznina, Alessandra Serva, Mathieu Salanne, Toshihiko Mandai, Tomooki Hosaka, Mirna Alhanash, Patrik Johansson, Yun-Ze Qiu, Hai Xiao, Michael Eikerling, Ryosuke Jinnouchi, Marko M Melander, Georg Kastlunger, Assil Bouzid, Alfredo Pasquarello, Seung-Jae Shin, Minho M Kim, Hyungjun Kim, Kathleen Schwarz, Ravishankar Sundararaman
Deliverables (7)
Other Results (1)
Periodic Reporting for period 1 - OPERA (DEVELOPMENT OF OPERANDO TECHNIQUES AND MULTISCALE MODELLING TO FACE THE ZERO-EXCESS SOLID-STATE BATTERY CHALLENGE)