Physicists Shatter Stubborn
Mystery of How Glass Forms
Waterloo News, [Ontario , Canada
Mystery of How Glass Forms
A physicist at the University
of Waterloo
Their simple theory is expected to open up the study of glasses to
non-experts and undergraduates as well as inspire breakthroughs in novel
nanomaterials.
The paper published by physicists from the University of Waterloo, McMaster
University, ESPCI ParisTech and Université Paris Diderot appeared in
the prestigious peer-reviewed journal, Proceedings of the National Academy
of Sciences (PNAS).
Glasses are much more than silicon-based materials in bottles and windows.
In fact, any solid without an ordered, crystalline structure — metal, plastic,
a polymer — that forms a molten liquid when heated above a certain temperature
is a glass. Glasses are an essential material in technology, pharmaceuticals,
housing, renewable energy and increasingly nano electronics.
“We were surprised — delighted — that the model turned out to be so
simple,” said author James Forrest, a University Research Chair and professor
in the Faculty of Science. “We were convinced it had already been published.”
The theory relies on two basic
concepts: molecular crowding and string-like co-operative movement. Molecular crowding describes
how molecules within glasses move like people in a crowded room. As the number
of people increase, the amount of free volume decreases and the slower people
can move through the crowd. Those people next to the door are able to move more
freely, just as the surfaces of glasses never actually stop flowing, even at
lower temperatures.
The more crowded the room, the more you rely on the co-operative movement
with your neighbours to get where you’re going. Likewise, individual molecules
within a glass aren’t able to move totally freely. They move with, yet are
confined by, strings of weak molecular bonds with their neighbours.
Theories of crowding and cooperative movement are decades old. This is the
first time scientists combined both theories to describe how a liquid turns
into a glass.
“Research on glasses is normally reserved for specialists in condensed
matter physics,” said Forrest, who is also an associate faculty member at
Perimeter Institute for Theoretical Physics and a member of the Waterloo
Institute for Nanotechnology. “Now a whole new generation of scientists
can study and apply glasses just using first-year calculus.”
Their theory successfully predicts everything from bulk behaviour to
surface flow to the once-elusive phenomenon of the glass transition itself.
Forrest and colleagues worked for 20 years to bring theory in agreement with
decades of observation on glassy materials.
An accurate theory becomes particularly important when trying to understand
glass dynamics at the nanoscale. This finding has implications for developing
and manufacturing new nanomaterials, such as glasses with conductive
properties, or even calculating the uptake of glassy forms of pharmaceuticals.
The paper’s co-authors include Thomas Salez, Justin Salez, Kari
Dalnoki-Veress and Elie Raphael.
The Natural Sciences and Engineering Research Council (NSERC) of Canada
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