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CMI technology for recovering rare earth elements from electronic waste is licensed to a company in Iowa, which describes the tech and how it is being used.
Using dynamic nuclear polarization (DNP)-enhanced 17O NMR we showed that large numbers of quantitative internuclear distances could be determined to effectively triangulate the positions of atoms in a surface site. The new experiment can be easily applied to almost any surface site with minimal synthetic modification.
Only a small fraction of metals in most industrial catalysts are active, inefficiently utilizing critical materials. We developed a simple and cost‑effective strategy to anchor isolated platinum atoms onto hybrid organic-inorganic surfaces with molecular‑level precision.
A multiscale modeling framework is developed for catalytic conversion in narrow linear nanopores connecting high-fidelity molecular dynamics (MD), Langevin simulation of rare passing processes & coarse-grained (CG) stochastic modeling on experimental time- and length scales. Anomalous pore diameter dependence of yield is successfully predicted.
The U.S. Department of Energy’s (DOE) Ames National Laboratory and the Critical Materials Innovation (CMI) Hub announced a new collaboration with Amazon to advance technologies that recover and recycle critical materials, such as battery-grade graphite, and essential minerals that power modern technologies.
CMI researchers at Ames National Laboratory conducted the research for this highlight
CMI researchers at Oak Ridge National Laboratory conducted the research for this highlight
CMI researchers at Colorado School of Mines conducted the research for this highlight
CMI researchers at Colorado School of Mines conducted the research for this highlight
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