The Interfacial Materials Chemistry group emphasizes MAS-NMR characterization, materials synthesis, design of electroactive materials (Mg-ion, Li-ion, Ca-ion), and structure-property relationships in both electrochemical energy storage and solid oxide fuel cell electrode materials with an emphasis on developing an understanding of the transport of cations across electrochemical interfaces.
The Solid State NMR group specializes in using high resolution MAS-NMR and static electrochemical in-situ NMR methods to characterize structure activity relationships, ionic mobility in bulk solids, and electrochemical interfaces for new energy storage chemistries. Our work includes utilizing quantitative NMR methodologies in paramagnetic systems to gain an understanding of the local structural changes that occur in a diverse range of electroactive materials including lithium rich cathodes, NMC surfaces, and silicon anodes. We have pioneered applying 25Mg NMR methodologies to magnesium-ion battery materials to gain a fundamental understanding of multivalent-ion battery chemistries.
Materials Synthesis: We collaborate across Argonne in the areas of materials design and synthesis, crystal growth, thin-film deposition, and electrochemical evaluation. Areas of interest include energy storage materials (cathode, anode, solid electrolytes), three dimensional electrode structures, new electrolytes, and identification of new materials.
Across Argonne, we are active members of
- Joint Center for Energy Storage Research (JCESR), a DOE Innovation Hub. We work with National Lab and University groups to design and develop the next generation of beyond Li-ion active materials for energy storage applications. We are active in the development of Zn-ion, Mg-ion, and Ca-ion based multivalent cation-based systems. We work with the Ceder Group at UC Berkeley utilizing the Materials Genome for materials discovery. https://materialsproject.org/
- Applied Battery Research Silicon (DeepDive): EEREs (VTO) Next Generation Anode Program is focused on identifying and solving the underlying causes of performance fade in Li-ion cells that contain silicon as a component of the anode. The program is a collaboration between Argonne, Oak Ridge, Pacific Northwest, Lawrence Berkeley, and the National Renewable Energy Laboratory (NREL).
- Applied Battery Research Silicon (SEISta): EEREs (VTO) SEISta program seeks to develop a better understanding of the Solid Electrolyte Interphase (SEI) and silicon-based electrochemical interfaces in a Li-ion cell. The program is a collaboration between the National Renewable Energy Laboratory (NREL), Argonne, Oak Ridge, Lawrence Berkeley, and Sandia.
- Applied Battery Research Cathodes: EEREs (VTO) Next Generation Cathode Program is a collaboration between Argonne, Oak Ridge, Lawrence Berkeley, and the National Renewable Energy Laboratory (NREL). The effort seeks to identify strategies to reduce the amount of cobalt in lithium-ion electrochemical cells.
- Lithium-Ion Battery Cathode Recycling (ReCell) : We combine new synthetic approaches with an understanding of the role of processing, sample history, and defect chemistry to identify new routes to reestablishing the electrochemical performance of recycled lithium-ion battery cathode materials. The program is a collaboration Argonne, the National Renewable Energy Laboratory, Oak Ridge, Worcester Polytechnic Institute, Michigan Technological University, and the University of California at San Diego.
- Solid Oxide Fuel Cell Program: Our Fossil Energy Program is focused on studying structure-property relationships in SOFC cathode materials.