Dielectric properties and vacancy‐like defects in plasma‐sprayed barium titanate

Positron annihilation spectroscopy was employed for investigation of vacancy‐like defects in plasma‐sprayed barium titanate. Defect studies were combined with measurement of dielectric properties of barium titanate coatings. Samples prepared by gas‐stabilized plasma spray (GSP) torch and by plasma t...

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Published in	Journal of the American Ceramic Society Vol. 100; no. 7; pp. 2972 - 2983
Main Authors	Ctibor, Pavel, Čížek, Jakub, Sedláček, Josef, Lukáč, František
Format	Journal Article
Language	English
Published	Columbus Wiley Subscription Services, Inc 01.07.2017
Subjects	Annealing Argon Barium barium titanate Coating Coatings Defects Dielectric properties Lattice vacancies Oxidation Oxygen Plasma spraying Positron annihilation Process parameters Stabilization Titanium vacancies
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Abstract	Positron annihilation spectroscopy was employed for investigation of vacancy‐like defects in plasma‐sprayed barium titanate. Defect studies were combined with measurement of dielectric properties of barium titanate coatings. Samples prepared by gas‐stabilized plasma spray (GSP) torch and by plasma torch with the hybrid water‐argon stabilization (WSP‐H) were studied. Processing parameters were selected so that GSP coatings were sprayed in reductive conditions, whereas WSP‐H coatings were prepared in oxidizing environment. As‐sprayed GSP coating is dark, whereas WSP‐H one is light. The dielectric properties of WSP‐H coating are superior to those for GSP one. Defect studies revealed that both GSP and WSP‐H coatings contain titanium vacancies. However, GSP coating contains in addition a considerable concentration of oxygen vacancies. Some fraction of oxygen vacancies in GSP coating is coupled with titanium vacancies forming partial Schottky defect. The structure of WSP‐H coating is less disordered and contains only a low concentration of oxygen vacancies. This is consistent with reductive and oxidizing conditions in GSP and WSP‐H spraying, respectively. Annealing at elevated temperatures in air leads to removal of oxygen vacancies which are filled by oxygen diffusing into the samples.
AbstractList	Positron annihilation spectroscopy was employed for investigation of vacancy‐like defects in plasma‐sprayed barium titanate. Defect studies were combined with measurement of dielectric properties of barium titanate coatings. Samples prepared by gas‐stabilized plasma spray (GSP) torch and by plasma torch with the hybrid water‐argon stabilization (WSP‐H) were studied. Processing parameters were selected so that GSP coatings were sprayed in reductive conditions, whereas WSP‐H coatings were prepared in oxidizing environment. As‐sprayed GSP coating is dark, whereas WSP‐H one is light. The dielectric properties of WSP‐H coating are superior to those for GSP one. Defect studies revealed that both GSP and WSP‐H coatings contain titanium vacancies. However, GSP coating contains in addition a considerable concentration of oxygen vacancies. Some fraction of oxygen vacancies in GSP coating is coupled with titanium vacancies forming partial Schottky defect. The structure of WSP‐H coating is less disordered and contains only a low concentration of oxygen vacancies. This is consistent with reductive and oxidizing conditions in GSP and WSP‐H spraying, respectively. Annealing at elevated temperatures in air leads to removal of oxygen vacancies which are filled by oxygen diffusing into the samples. Positron annihilation spectroscopy was employed for investigation of vacancy‐like defects in plasma‐sprayed barium titanate. Defect studies were combined with measurement of dielectric properties of barium titanate coatings. Samples prepared by gas‐stabilized plasma spray ( GSP ) torch and by plasma torch with the hybrid water‐argon stabilization ( WSP ‐H) were studied. Processing parameters were selected so that GSP coatings were sprayed in reductive conditions, whereas WSP ‐H coatings were prepared in oxidizing environment. As‐sprayed GSP coating is dark, whereas WSP ‐H one is light. The dielectric properties of WSP ‐H coating are superior to those for GSP one. Defect studies revealed that both GSP and WSP ‐H coatings contain titanium vacancies. However, GSP coating contains in addition a considerable concentration of oxygen vacancies. Some fraction of oxygen vacancies in GSP coating is coupled with titanium vacancies forming partial Schottky defect. The structure of WSP ‐H coating is less disordered and contains only a low concentration of oxygen vacancies. This is consistent with reductive and oxidizing conditions in GSP and WSP ‐H spraying, respectively. Annealing at elevated temperatures in air leads to removal of oxygen vacancies which are filled by oxygen diffusing into the samples.
Author	Lukáč, František Ctibor, Pavel Sedláček, Josef Čížek, Jakub
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Snippet	Positron annihilation spectroscopy was employed for investigation of vacancy‐like defects in plasma‐sprayed barium titanate. Defect studies were combined with... Positron annihilation spectroscopy was employed for investigation of vacancy-like defects in plasma-sprayed barium titanate. Defect studies were combined with...
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SubjectTerms	Annealing Argon Barium barium titanate Coating Coatings Defects Dielectric properties Lattice vacancies Oxidation Oxygen Plasma spraying Positron annihilation Process parameters Stabilization Titanium vacancies
Title	Dielectric properties and vacancy‐like defects in plasma‐sprayed barium titanate
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