Noble metals such as platinum can make useful catalysts to accelerate chemical reactions, particularly hydrogenation (adding hydrogen atoms to a molecule). The research team led by Professor Bruce Gates at the UC Davis Department of Chemical Engineering is interested in making platinum catalysts that are highly efficient and stable during chemical reactions.
Previous work has shown that platinum arranged in clusters of a few atoms on a surface makes a better hydrogenation catalyst than either single platinum atoms, or larger nanoparticles of platinum. Unfortunately, such small clusters tend to clump easily into larger particles, losing efficiency.
Yizhen Chen, then a postdoctoral scholar in the Gates Catalysis Research Group, picked up on an idea by Jingyue Liu, now at Arizona State University, to “trap” platinum clusters on a tiny island of cerium oxide supported on a silica surface. Each island becomes its own chemical reactor.
Chen, Gates and colleagues were able to show that they could produce these clusters, that they showed good catalytic activity in hydrogenation of ethylene, and that they were stable under severe reaction conditions.
These confined metal clusters could provide a new route to produce stable catalysts for the chemical industry.
Scientists develop new method to isolate atomic sheets and create new materials
Two-dimensional materials from layered van der Waals (vdW) crystals hold great promise for electronic, optoelectronic, and quantum devices, but making/manufacturing them has been limited by the lack of high-throughput techniques for exfoliating single-crystal monolayers with sufficient size and high quality.
The concept is based on the interaction of resonant semiconductor iron oxide Fe2O3 nanoparticles with light. Particles previously loaded with the antitumor drug are injected in vivo and further accumulate at the tumor areas. In order to release the drug non-invasively, the carrier particles have to be light-sensitive. For this purpose, the polymer containers (capsules) can be modified with iron oxide resonant semiconductor nanoparticles. When irradiated with light, they get heated and induce drug release.
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