Energy Materials & Processes
Energy Materials and Processes focuses on the dynamic transformation mechanisms and physical and chemical properties at critical interfaces in catalysts and energy materials needed to design new materials and systems for sustainable energy applications. By facilitating the development and rapid dissemination of critical molecular-level information along with predictive modeling of interfaces and their unique properties EMSL helps enable the design and development of practical, efficient, environmentally benign and economic energy storage and energy conversion systems.
- Solvent-mediated Interfacial Chemistry: Develop sufficient understanding of the dynamic and emergent processes that occur at solvent-mediated interfaces to predict the transformation mechanisms and physical and chemical properties needed to design advanced batteries and new catalysts for degradation of biomass and upgrading of bioproduced fuels and renewable chemicals.
Energy Materials and Processes focuses on the dynamic transformation mechanisms and physical and chemical properties at critical interfaces in catalysts and energy materials needed to design new materials and systems for sustainable energy applications. By facilitating the development and rapid dissemination of critical molecular-level information along with predictive modeling of interfaces and their unique properties EMSL helps enable the design and development of practical, efficient, environmentally benign and economic energy storage and energy conversion systems.
- Solvent-mediated Interfacial Chemistry: Develop sufficient understanding of the dynamic and emergent processes that occur at solvent-mediated interfaces to predict the transformation mechanisms and physical and chemical properties needed to design advanced batteries and new catalysts for degradation of biomass and upgrading of bioproduced fuels and renewable chemicals.
EMSL's annual call for proposals opens in early January
Imaging results are ones for the books
Understanding NOx SCR and soot oxidation processes on multi-functional SCR-based materials
Coking- and sintering-resistant surface-mounted sub-nano cluster catalysts of endothermic cooling
Thermal Aging Degradation Mechanisms of Cast Austenitic Stainless Steels
Characterization of Novel Rapidly Solidified and Nanostructured Alloys
Combined Surface Characterization and Computation Study of a LaxZryOz Catalyst for the Catalytic Upgrading of Biomass-derived
Quantum Chemistry of MetalOrganic Frameworks
Hydrogen Uptake and Release in Condensed Phases
Pages
Leads
Dr. Baer is EMSL's science theme lead for Molecular Transformations. As lead he implements the vision for development and implementation of scientific leadership within that area of emphasis, including objectives, targets and assembling the...