Liten is a major European research institute and a driving force behind the development of the sustainable energy technologies of the future. The institute is spearheading the EU’s efforts to limit dependency on fossil fuels and reduce greenhouse gas emissions in three key areas: renewable energy, energy efficiency/storage and development of materials.
Our platforms, sophisticated tools for industry & the scientific/technical infrastructure/expertise to overcome technological hurdles
Liten's research teams work across a vast portfolio of renewable energy technologies. Cutting-edge photovoltaic technologies are developed at INES, the French National centre for solar research and R&D with Hydrogen and Biomass activities being managed from the LITEN's main site in Grenoble, Rhone-Alpes.
“Radically improving energy efficiency will reduce the need for investment in energy infrastructure, cut fuel costs, increase competitiveness, lessen exposure to fuel price volatility, increase energy affordability for low-income households and cut local and global pollutants improving consumer welfare” Source OECD Energy report, 2014
From nanosecurity, nanocharacterisation,and anti-counterfeiting technology to the development of advanced materials and point of sale: a comprehensive offering.
Transverse activities help add value to our technology portfolio. An optimised modeling and characterisation model, for example, can help reduce time to market. Browse this section to find out more....
The FOCUS program
"Multiscale battery simulation applied to electrode materials" aims to develop a
more predictive simulation approach in the field of
Li-ion batteries. This approach is based on a
strong coupling between physical modeling and experimental characterization. The simulation models and software developed within this program will be a complementary tool to the experience to accelerate the development and synthesis of more efficient, durable and safe materials and electrodes.
In this context, the CEA is launching fifteen theses and post-docs to enrich the skills invested in this ambitious project.
Li-ion batteries are complex systems involving multiple coupled physico-chemical and multi-scales phenomena. Integrating this multi-scale approach is essential to, in the upward direction, have less empirical and more predictive models based on the underlying physical phenomena, and in the downward direction, orient developments towards problems of interest at higher scales. If a predictive approach based on modeling and simulation is relevant at any scale to make improvements and innovations on Li-ion batteries, it is probably at the material scale that ruptures are most likely to emerge.
This is why the FOCUS program focuses on these scales and integrates two parallel and complementary paths. The first one aims to improve current technologies known and available through greater use of modeling and simulation in a process of development-characterization-modeling-simulation coupling and by ensuring consistency between the different scales. The second path aims to accelerate the development of new materials for the emergence of innovative technologies including solid electrolyte batteries. This second path will benefit from the contribution of the first one in terms of overall approach (link between scales, coupling, characterization, modeling, simulation, validation, etc.).
Aging of Li-ion batteries with a silicon anode studied by radiolysis
Study of Lithium-plating phenomenon: Characterization and phenomenon simulation
Study of heterogeneous damage in Li-ion batteries related to cell design and development of associate ageing model at cell level
Modeling phase transitions in LIB active materials
Study of the Li intercalation mechanisms in battery electrodes by operando synchrotron X-ray (micro)diffraction
Study of cathode materials for lithium-ion batteries by experimental and theoretical soft and hard X-ray photo-emission spectroscopy
Theoretical and experimental study of the kinetics of lithiation of amorphous and cristalline silicon
Operando characterization of the battery structure and interfaces using 3D synchrotron/neutron techniques
Study of the mechanical behaviour in cycling of a silicon/carbon composite particle used in Li-Ion cells
Selection and optimisation of silicon anodes for all solid state batteries
In-situ visualization and quantification of microstructural evolutions in all-solid batteries
Atomic-scale modelling of glass/crystal electrolyte materials for solide state batteries
Multiscale modeling of lithium transport in solid and hybrid Li-ion electrolytes and their interfaces
Study of transport mechanisms of lithium in hybrid electrolytes for solid-state batteries
CEA is a French government-funded technological research organisation in four main areas: low-carbon energies, defense and security, information technologies and health technologies. A prominent player in the European Research Area, it is involved in setting up collaborative projects with many partners around the world.