Synthesis of hyperbranched perovskite nanostructures

Ting Yang; Zachary D. Gordon; Candace Chan

doi:10.1021/cg4005483

Synthesis of hyperbranched perovskite nanostructures

Ting Yang, Zachary D. Gordon, Candace Chan

Research output: Contribution to journal › Article › peer-review

16 Scopus citations

Abstract

Complex functional perovskite oxides find use in a wide range of applications as dielectric, electronic, photocatalytic, optical, and ion-conducting materials. The ability to synthesize perovskites in hierarchical structures can allow for new properties or phenomena not observable in bulk morphologies. Herein we report on the solution-phase synthesis of cubic perovskite potassium lanthanum titanate into orthogonal nanostructures with hyperbranched and hexapod morphology through a facile hydrothermal synthesis without using a template, catalyst, substrate, or structure-directing agent. A systematic study of the reaction conditions and role of precursors was performed and a growth mechanism based on homogeneous dissolution-precipitation was determined.

Original language	English (US)
Pages (from-to)	3901-3907
Number of pages	7
Journal	Crystal Growth and Design
Volume	13
Issue number	9
DOIs	https://doi.org/10.1021/cg4005483
State	Published - Sep 4 2013

ASJC Scopus subject areas

Chemistry(all)
Materials Science(all)
Condensed Matter Physics

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AB - Complex functional perovskite oxides find use in a wide range of applications as dielectric, electronic, photocatalytic, optical, and ion-conducting materials. The ability to synthesize perovskites in hierarchical structures can allow for new properties or phenomena not observable in bulk morphologies. Herein we report on the solution-phase synthesis of cubic perovskite potassium lanthanum titanate into orthogonal nanostructures with hyperbranched and hexapod morphology through a facile hydrothermal synthesis without using a template, catalyst, substrate, or structure-directing agent. A systematic study of the reaction conditions and role of precursors was performed and a growth mechanism based on homogeneous dissolution-precipitation was determined.

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Synthesis of hyperbranched perovskite nanostructures

Abstract

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