Defect Structure, Phase Separation, and Electrical
Properties of Nonstoichiometric Tetragonal Tungsten Bronze Ba<sub>0.5–<i>x</i></sub>TaO<sub>3–<i>x</i></sub>
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Abstract
New
insight into the defect chemistry of the tetragonal tungsten bronze
(TTB) Ba<sub>0.5–<i>x</i></sub>TaO<sub>3–<i>x</i></sub> is established here, which is shown to adapt to
a continuous and extensive range of both cationic and anionic defect
stoichiometries. The highly nonstoichiometric TTB Ba<sub>0.5–<i>x</i></sub>TaO<sub>3–<i>x</i></sub> (<i>x</i> = 0.25–0.325) compositions are stabilized via the
interpolation of Ba<sup>2+</sup> cations and (TaO)<sup>3+</sup> groups
into pentagonal tunnels, forming distinct Ba chains and alternate
Ta-O rows in the pentagonal tunnels along the <i>c</i> axis.
The slightly nonstoichiometric Ba<sub>0.5–<i>x</i></sub>TaO<sub>3–<i>x</i></sub> (<i>x</i> = 0–0.1) compositions incorporate framework oxygen and tunnel
cation deficiencies in the TTB structure. These two mechanisms result
in phase separation within the 0.1< <i>x</i> < 0.25
nonstoichiometric range, resulting in two closely related (TaO)<sup>3+</sup>-containing and (TaO)<sup>3+</sup>-free TTB phases. The highly
nonstoichiometric (TaO)<sup>3+</sup>-containing phase exhibits Ba<sup>2+</sup> cationic migration. The incorporation of (TaO)<sup>3+</sup> units into the pentagonal tunnel and the local relaxation of the
octahedral framework around the (TaO)<sup>3+</sup> units are revealed
by diffraction data analysis and are shown to affect the transport
and polarization properties of these compositions