APS March Meeting 2017
Volume 62, Number 4
Monday–Friday, March 13–17, 2017;
New Orleans, Louisiana
Session C37a: Dielectric and Ferroelectric Oxides I
2:30 PM–5:30 PM,
Monday, March 13, 2017
Room: 383
Sponsoring
Unit:
DMP
Chair: Mutgar Ahart, Carnegie Institute of Washington
Abstract ID: BAPS.2017.MAR.C37a.1
Abstract: C37a.00001 : Ferroelectric oxide thin films for advanced energy applications
2:30 PM–3:06 PM
Preview Abstract
Abstract
Author:
Sanghan Lee
(Gwangju Institute of Science and Technology)
Ferroelectrics are considered as promising photoanode materials because
their high built-in-potential due to their spontaneous polarizations can
largely enhance the separation and drift of photo-generated carriers.
Especially, among ferroelectrics, BiFeO$_{\mathrm{3}}$ has different
spontaneous polarizations and ferroelectric domain structure depending on
the crystallographic orientations, so it is of great significance to clarify
the direct relationship between photocatalytic properties, spontaneous
polarizations and ferroelectric domain structures. However, the
photocatalytic properties of epitaxial BiFeO$_{\mathrm{3}}$ thin film
photoanodes with different crystallographic orientations and subsequently
different ferroelastic domain structures have not been systematically
studied yet. Furthermore, the effect of ferroelectric switching on the PEC
properties of epitaxial BiFeO$_{\mathrm{3}}$ thin film photoanodes has not
been identified.
Considering the above, in this study, the most enhanced photocatalytic
performances of our BiFeO$_{\mathrm{3}}$ thin film photoanodes showed in the
(111)$_{\mathrm{pc}}$ BiFeO$_{\mathrm{3}}$ thin film photoanode, due to its
high spontaneous polarization and mono-variant domain structure, which was
approximately a 5.3 times larger photocurrent density at 0 V \textit{vs.} Ag/AgCl and a
0.180 V shift in the onset potential in comparison with the
(001)$_{\mathrm{pc}}$ BiFeO$_{\mathrm{3}}$ thin film photoanode in the
downward polarization. Furthermore, ferroelectric polarization switching in
the (111)$_{\mathrm{pc}}$ BiFeO$_{\mathrm{3}}$ thin film photoanode caused
an approximate change of 8,000{\%} in the photocurrent density at 0 V \textit{vs.}
Ag/AgCl and 0.330 V shift in the onset potential. We believe that
domain-engineered ferroelectric materials can be used as an effective charge
separation and collection layer for effective solar water splitting
photoanodes.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2017.MAR.C37a.1