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Passivation interfacial layers define the energy storage limits for next-generation batteries. It is crucial to understand how the bonding in salts, electrolytes, and solid electrodes can be used to tailor ion transport and to understand how these correlate to the formation of interfacial passivation layers. One of the routes that we have explored is to design task-specific ionic liquids and lithium salts to form stable, ionically conducting solid electrolyte interphase (SEI) layers in a controlled fashion.
After understanding these formation mechanisms and their advantages and disadvantages, we have also endeavored to create optimal artificial SEI layers that mimic these naturally formed SEI layers. On solid electrolytes, stabilizing interfaces in all-solid-state batteries (ASSBs) is crucial for the development of high-energy-density ASSBs. A facile, non-invasive, electrochemical protocol is explored to improve the interfacial impedance and contact at the interface of the solid electrolyte and electrode.
One of the requirements for next-generation batteries is extreme fast charging. A consequence of fast charging is severe lithium plating with graphite as the anode. To mitigate the lithium plating issue, other anode materials are explored, such as Li4Ti5O12 (LTO) and TiNb2O7 (TNO). We probe the question if LTO do or do not form an SEI layer, and we evaluate TNO as an anode material for extreme fast-charge applications. We also study the coating of separators with ceramic for increased safety and performance.
In all these studies, we have probed the surface via XPS and, where possible, via operando small-angle neutron scattering. The surface of solid polymer electrolytes, that could be argued to be the intermediate solution to all-SSBs, have been investigated in terms of their thermal degradation via in situ thermal XPS. The question that arises is whether temperature or the X-ray radiation induces the degradation.
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Dr. Charl Jafta
Oak Ridge National Laboratory
Dr. Charl Jafta has been an Associate R&D staff member in the Energy and Transport Science Division (ETSD) at Oak Ridge National Laboratory since April 2019. He joined ORNL in April 2017 as a postdoctoral research associate in the Chemical Science Division (CSD), where he worked on a BES funded project focusing on Materials and Interfacial Chemistry for Next Generation Electrical Energy Storage. Prior to joining ORNL, he worked as an instrument scientist at the V4 SANS instrument at Helmholtz-Zentrum Berlin. He earned his PhD in Physics at the University of Pretoria and his MSc in Surface Physics at the University of the Free State, where he also received his BSc and BSc (Hons) in Physics and Applied Mathematics. His current main focus is on studying the interfaces in solid state battery systems and using operando neutron scattering techniques to characterize known and novel battery chemistries. The general direction of his research is in energy storage materials. Dr. Jafta has published over 80 peer reviewed articles in prominent journals, has 2 granted patents, 2 patent applications, and has authored 3 book chapters.