College Park, MD (June 22, 2010) — The secret life of water just got weirder. For years water has been known to exist in 15 phases — not just the merry threesome of solid, liquid and gas from grade school science. Now, University of Utah chemists have confirmed the coexistence of ice and liquid after water crystallizes at very low temperatures. They describe their work in the June 21 issue of the Journal of Chemical Physics, which is published by the American Institute of Physics (AIP).
It takes more than a swizzle stick and a cocktail shaker to do this kind of ice research. It takes a temperature of 180 K, an extremely cold temperature typical of the upper atmosphere called the “no-man’s land” of water because of the curious blurring of two water phases — liquid and ice — that occurs there.
“This blurring is what’s interesting,” says Valeria Molinero, who led the research. “Our findings show that what goes on there is important to the behavior of water and to the formation of clouds.”
Molinero and graduate student Emily Moore discovered that at 180 K rapid ice crystallization makes it difficult to follow the process. Because the molecules move too quickly to observe directly in the lab, their investigation used computer simulations.
By targeting this critical temperature zone, their work might be important for understanding cloud formations that regulate global radiation and hence climate change. While this is a boon for understanding supercooled water and its role in cloud formation, it’s a breakthrough for those dreaming of a No Man’s Land Physics Fun Park. One day, they just might play hockey while swimming.
The article, “Ice Crystallization in Water’s “No-Man’s Land” by Emily Moore and Valeria Molinero will appear in the Journal of Chemical Physics. See: http://jcp.aip.org/
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ABOUT THE Journal of Chemical Physics
The Journal of Chemical Physics publishes concise and definitive reports of significant research in methods and applications of chemical physics. Innovative research in traditional areas of chemical physics such as spectroscopy, kinetics, statistical mechanics, and quantum mechanics continue to be areas of interest to readers of JCP. In addition, newer areas such as polymers, materials, surfaces/interfaces, information theory, and systems of biological relevance are of increasing importance. Routine applications of chemical physics techniques may not be appropriate for JCP. Content is published online daily, collected into four monthly online and printed issues (48 issues per year); the journal is published by the American Institute of Physics. See: http://jcp.aip.org/
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