Silica-metal core-shells and metal shells synthesized by porphyrin-assisted photocatalysis. Synthesis of platinum nanowheels using a bicellar template. Metal oxide composites and structures for ultra-high temperature solar thermochemical cycles. Impact of copper on the performance and sulfur tolerance of barium-based NO x storage-reduction catalysts. Journal of Solar Energy Engineering 130(4):041001. Solar thermochemical water-splitting ferrite-cycle heat engines. Two-step water splitting using mixed-metal ferrites: Thermodynamic analysis and characterization of synthesized materials. Morphological families of self-assembled porphyrin structures and their photosensitization of hydrogen generation. Methanol production from CO 2 using solar-thermal energy: process development and techno-economic analysis. Templated growth of platinum nanowheels using the inhomogeneous reaction environment of bicelles. Ferrite-YSZ composites for solar thermochemical production of synthetic fuels: in operando characterization of CO 2reduction. Journal of Porphyrins and Phthalocyanines 15(05n06):449-458. Evolution of dendritic nanosheets into durable holey sheets: a lattice gas simulation study. Coextrusion of zirconia-iron oxide honeycomb substrates for solar-bsed thermochemical generation of carbon monoxide for renewable fuels. Chemical Engineering Science 84(Dec):372-380. Solar thermal decoupled water electrolysis process I: Proof of concept. Energy and Environmental Science 5:8417-8429. Fuel production from CO 2 using solar-thermal energy: System level analysis. Using in-situ techniques to probe high-temperature reactions: Thermochemical cycles for the production of synthetic fuels from CO 2 and water. Journal of Materials Chemistry 22:6726-2732. Oxygen transport and isotopic exchange in iron oxide/YSZ thermochemically-active materials via splitting of C( 18O) 2 at high temperature studied by thermogravimetric analysis and secondary ion mass spectrometry. BS, Chemical Engineering, Texas A&M University, 1986Ĭoker, E.PhD, Chemical Engineering, University of Texas-Austin, 1992.Miller received his BS in Chemical Engineering from Texas A&M University in 1986, and his PhD in Chemical Engineering from the University of Texas at Austin in 1992. Miller has co-authored over 120 technical documents, holds 10 patents, and is the recipient of two R&D 100 Awards. He led and contributed directly to efforts in materials development and characterization, development of new high temperature thermochemical reactors and systems, and thermodynamic, engineering and technoeconomic analysis. He served as the principle investigator of the large multi-institution and –discipline solar thermochemical efforts for solar fuels (Sunshine to Petrol) and thermochemical energy storage (PROMOTES). Prior to joining ASU LightWorks® in 2018, he worked at Sandia National Laboratories for over 25 years where his work touched on diverse topics ranging from catalysis for a variety of reactions to desalination. Miller (Jim) is a chemical engineer who has directed his efforts towards energy, materials, and chemical processing research. Professor of Practice, LightWorks ®, Global Institute of Sustainability and Innovation.Professor of Practice, School of Sustainability, College of Global Futures.Senior Global Futures Scientist, Julie Ann Wrigley Global Futures Laboratory.