Affiliation:
1. Department of Materials Science and Engineering University of California, Berkeley Berkeley CA 94720 USA
2. Materials Sciences Division Lawrence Berkeley National Laboratory Berkeley CA 94720 USA
3. Department of Chemistry University of Pennsylvania Philadelphia PA 19104‐6323 USA
4. Department of Chemistry Washington University in St. Louis St. Louis MO 63130 USA
5. Department of Physics Oklahoma State University Stillwater OK 74078 USA
Abstract
AbstractComplex‐oxide superlattices provide a pathway to numerous emergent phenomena because of the juxtaposition of disparate properties and the strong interfacial interactions in these unit‐cell‐precise structures. This is particularly true in superlattices of ferroelectric and dielectric materials, wherein new forms of ferroelectricity, exotic dipolar textures, and distinctive domain structures can be produced. Here, relaxor‐like behavior, typically associated with the chemical inhomogeneity and complexity of solid solutions, is observed in (BaTiO3)n/(SrTiO3)n (n = 4–20 unit cells) superlattices. Dielectric studies and subsequent Vogel–Fulcher analysis show significant frequency dispersion of the dielectric maximum across a range of periodicities, with enhanced dielectric constant and more robust relaxor behavior for smaller period n. Bond‐valence molecular‐dynamics simulations predict the relaxor‐like behavior observed experimentally, and interpretations of the polar patterns via 2D discrete‐wavelet transforms in shorter‐period superlattices suggest that the relaxor behavior arises from shape variations of the dipolar configurations, in contrast to frozen antipolar stripe domains in longer‐period superlattices (n = 16). Moreover, the size and shape of the dipolar configurations are tuned by superlattice periodicity, thus providing a definitive design strategy to use superlattice layering to create relaxor‐like behavior which may expand the ability to control desired properties in these complex systems.
Funder
National Science Foundation
Army Research Office
Subject
Mechanical Engineering,Mechanics of Materials,General Materials Science
Cited by
1 articles.
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