Nanoscale domain control in multiferroic BiFeO3 thin films

Publication Type	Journal Article

Authors	Y.-H Chu Q Zhan L.W Martin M.P Cruz P.-L Yang G.W Pabst F Zavaliche S.-Y Yang J.-X Zhang L.-Q Chen D.G Schlom I.-N Lin T.-B Wu Ramamoorthy Ramesh
DOI	10.1002/adma.200601098
Abstract	The growth of highly ordered 1D ferroelectric domains in 120nm thick BiFeO_{3(BFO) films was investigated. Transducers, microelectromechanical (MEMS) systems applications, materials with superior ferroelectric, and piezoelectric responses are became interesting with an ever-expanding demand for data storage. BFO provides a choice as a green ferro/piezoelectric material and its high ferroelectric Curie temperature enables it to be used reliably at high temperature. The ferroelectric domain structure of an epitaxial BFO film has been modeled using the phase-field method in which the spatial distribution of the polarization field and its evolution is described by the time-dependent Ginzburg-Landau(TDGL) equations. Carefully controlling the growth mechanism for the SRO layer, the IP lattice parameters of SRO films are pinned by DSO substrate to create the 1D periodic domain structure.}
Notes	cited By 219
Journal	Advanced Materials
Volume	18
Year of Publication	2006
Number	17
Pagination	2307-2311
ISSN Number	09359648
Keywords	thin films Polarization spatial distribution Transducers bismuth compounds piezoelectricity Magnetic domains Piezoelectric materials Microelectromechanical devices Curie temperature IP lattice parameters Time-dependent Ginzburg-Landau(TDGL) equations
Research Areas	Ramesh Lab
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