Initially, researchers at the NIST Combinatorial Methods Center (NCMC) and several of the NCMC's company members plan to rev up the search for new or better emulsions--often-complex formulations that are the basis for U.S. product markets totaling more than $50 billion. They will start by deciphering interactions at the interfaces (inter-facial tension) between the various components that make up these viscous mixtures and are key to their performance.
Now, efforts to improve paints, shampoos and other emulsions tend to be time-consuming, trial-and-error exercises. But with tiny "lab-on-chip" devices, much of the process can be automated, permitting rapid, systematic testing of new material formulations.
The project will extend the capabilities of so-called microfluidic systems--tiny, channel-lined devices now used regularly for medical testing. In DNA chips, for example, droplets of genetic material are routed through networks of tiny wells, each one set up for a particular diagnostic test. Material formulations, however, typically contain components--from solvents to different-sized particles--that do not readily mix and circulate through these minute plumbing systems. To accommodate these differences, NCMC researchers have designed and tested credit-card-sized prototypes tailored for viscous materials research. Features include mixers, pumps, reservoirs and computer control of the flow of sample droplets through a network of millimeter-wide channels. Mixture properties will be characterized with real-time image measurement techniques that NIST is developing with an eye on many application areas.