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Topic Name: Important information about the mechanical properties of thin films
Category: Advanced Materials
Research persons: Thomas Russell and his colleagues
Location: University of Massachusetts Amherst ,120 Governors Drive,Amherst, MA 01003, United States
Details
A remarkably simple experiment devised by scientists yields important
information about the mechanical properties of thin films--nanoscopically thin
layers of material that are deposited onto a metal, ceramic or semiconductor
base.
The research results, funded by the National Science Foundation and performed
at the University of Massachusetts at Amherst Materials Research Science and
Engineering Center, appears in the August 3, 2007, issue of Science.
The findings impact a broad range of scientific disciplines and applications,
from cosmetics to coatings, to micro- and nanoelectronics. Understanding the
mechanical properties of thin films is essential to their performance and
optimization.
Until now, determining the mechanical properties of these thin films was
either an expensive and time-consuming endeavor, requiring powerful microscopes
to view the films, or scientists examined composite structures and made
uncertain assumptions. This new research will give scientists a simple way to
access the material properties of most thin films.
"As we delve more into the nanotechnology, it becomes increasingly important
to know if the material properties of ultrathin films differ from their
properties in the bulk," said Thomas Russell, a program director in the Polymer
Science and Engineering Department at the University of Massachusetts in
Amherst. "Everyday we see examples where a material's dimensions can change its
properties. Aluminum foil is flexible, whereas a bar of aluminum is not. But
what happens when a film's thickness approaches molecular dimensions? These
experiments give us a simple, inexpensive way to measure mechanical properties
of films that are only tens of nanometers thick."
Russell and his colleagues use a low-power optical microscope to observe what
happens when they place a tiny drop of water on thin film as it floats in a
Petri dish of water. The "capillary tension" of the drop of water produces a
starburst of wrinkles in the film. The number and length of the wrinkles are
determined by the elasticity and thickness of the film.
In some of the materials studied, the wrinkles in the ultrathin polymer films
vanished with time, unlike the skin of a dried fruit or the crumpled hood of
your car after an accident. This vanishing provides insight into the relaxation
process of an ultrathin film by yielding information on the way polymer chains
move in the highly confined geometry.
About Researchers:
Thomas Russell,
Department of Polymer Science and Engineering
Room A516, Conte Research Center
University of Massachusetts Amherst
120 Governors Drive
Amherst, MA 01003
Phone: 413-545-2680
Email: russell@mail.pse.umass.edu
Fax: 413-577-1510
Funded:
The National Science
Foundation (NSF)
In The Images:
1.Thomas Russell,2.A starburst of wrinkles form in a thin film material when a drop of water is placed on the film.
| Tags: |
nanoscopically - thin films - nanoelectronics - cosmetics coatings - Aluminum foil - confined geometry - |
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