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Topic Name: Shocking: Environmental chemistry affects ferroelectric film polarity the same way electric voltage does
Category: Environmental engineering
Research persons: Brian Stephenson
Location: Illinois, United States
Details
“Ferroelectric materials are interesting scientifically, and, while they are
used for some things now, they are potentially useful for even more applications
in the future,” Brian Stephenson says. Stephenson is a scientist at Argonne
National Laboratory in Argonne, Illinois. He has been working on a project to
study chemical switching in a ferroelectric film.
“Normally,” Stephenson continues, “voltage is applied to change the internal
structure in ferroelectric materials. You can turn the crystal upside down from
the internal point of view. We have shown, I think for the first time, that this
can also be done chemically by changing the chemistry of the environment.” The
results of the work, which includes scientists from Northern Illinois University
and the University of Pennsylvania as well as Argonne, can be found in Physical
Review Letters: “Reversible Chemical Switching of a Ferroelectric Film.”
In order to test the process of chemical switching by changing the environment
of the ferroelectric film, Stephenson and his colleagues varied the oxygen
partial pressure. In situ x-ray scattering was used to “see” the changes in the
polarization of the material. The specific ferroelectric material used for the
experiment was lead titanate (PbTiO3). The group found that changing the oxygen
pressure switched the polarization of the PbTiO3 film in much the same way as
the conventional practice of using electrodes and voltage.
The use of x-rays is important, since it allows scientists a peek at what is
actually happening inside these materials. “The challenge has been to measure
what is going on,” Stephenson admits. “With these thin films, external voltage
measurements become more ambiguous. With our x-ray technique, we are able to
watch the atomic-scale structure inside these systems.”
“Up until now,” he continues, “we didn’t really think that the environment these
ferroelectric materials were in could be just as important as the voltage
applied. Fundamentally, we didn’t realize that extra oxygen or missing oxygen at
the surface could produce an electric field big enough to affect properties.”
This knowledge will become more important, Stephenson explains, as the demand
for smaller devices made from new materials increases. Infrared and terahertz
technology, controllable catalysts and chemistry applications on chips represent
some of the areas that might benefit from a better knowledge of how switching
works with PbTiO3 films.
“Already there are ferroelectric materials used for non-volatile computer memory
devices,” Stephenson points out. “But the holy grail of these is a memory
element the size of an atom. As films get thinner, understanding the interfacial
properties of these materials makes a difference. If the chemistry of the
environment can change the polarization, we need to harness this to create new
types of devices.”
“The big picture is that we are trying to create new functional materials with
interesting properties. We want to understand the way interfaces between
different materials work. Ferroelectrics provide a model system where we can
produce and measure large effects of the electric fields from the interfaces.”
| Tags: |
Ferroelectric material - ferroelectric film polarity - Environmental chemistry affects ferroelectric film polarity - chemical switching - - |
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