Chemical catalysts are the change agents behind the production of just about everything we use in our daily lives, from plastics to prescription drugs. When the right catalysts are mixed with the right chemical compounds, molecules that would otherwise take years to interact do so in mere seconds.<\/p>\n
However, developing even one catalyst material to trigger this precise choreography of atoms can take months, even years, when using traditional wet chemistry procedures that use only chemical reactions, often in the liquid phase, to grow nanoparticles.<\/p>\n
Ä¢¹½´«Ã½ researchers say there is a way to shorten that process dramatically\u2014by instead using pulsed lasers in liquids to quickly create carefully tuned, systematic arrays of nanoparticles that can be easily compared and tested for use as catalysts.<\/p>\n
The process is described in a Chemical Reviews<\/em> article<\/a> by Astrid M\u00fcller<\/a>, an assistant professor of chemical engineering<\/a> at the Ä¢¹½´«Ã½<\/a> who has adapted the technique for her work on sustainable energy solutions. Three PhD students in her lab\u2014coauthors Ryland Forsythe, Connor Cox, and Madeleine Wilsey\u2014conducted an exhaustive review of almost 600 previous papers involving the use of pulsed lasers in liquids. As a result, their article is the most comprehensive, up-to-date survey of a technology that was first developed in 1987.<\/p>\n