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SYNTHESIS, CHARACTERIZATION, AND SELF-CONTROLLED ORTHORHOMBIC TO TETRAGONAL POLYMORPHIC TRANSFORMATION IN BaTiO₃ NANOPARTICLES

S. RAM

Materials Science Centre, Indian Institute of Technology, Kharagpur 721 302, India

Corresponding author.

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A. JANA

Department of Physics, Saldiha College, Bankura, India

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, and

T. K. KUNDU

Department of Physics, Visva-Bharati, Santiniketan, Birbhum 731235, India

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https://doi.org/10.1142/S0217984907014115Cited by:0 (Source: Crossref)

Abstract

The phase formation and thermal-induced phase transformation are studied in BaTiO₃ nanoparticles. 2 h of heating a polymer precursor at 550°C in air formed a single phase BaTiO₃ of 15 nm average crystallite size D. The X-ray diffraction peaks are analyzed assuming a P_nma orthorhombic (o) crystal structure of lattice parameters a = 0.6435 nm, b = 0.5306 nm, and c = 0.8854 nm. The lattice volume V = 0.3023 nm³, with z = 4 formula units, yields a density ρ = 5.124 g/cm³. This is a new polymorph in comparison to well-known P_m3m tetragonal (t) structure, V = 0.0644 nm³ or ρ = 6.016 g/cm³ (z = 1). An o ↦ t transformation appears on heating at temperature as high as 650°C in air. A proposed model explains the transformation above a certain D value in terms of the Gibbs free energy. Unless heating above 750°C, the two phases coexist in a composite structure (D≤27 nm), with as much residual o-phase trace as ~28 vol%. As a function of temperature both the phases decrease in the V values up to 0.2975 and 0.0643 nm³ at 750°C respectively (0.0650 nm³ at 650°C). This is an important parameter for designing useful ferroelectric and other properties in a hybrid composite structure.

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