Synthesis, Structure and Electrical Properties of Donor Doped Barium Titanate Ceramics
Research output: Thesis › Doctoral Thesis
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2016.
Research output: Thesis › Doctoral Thesis
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T1 - Synthesis, Structure and Electrical Properties of Donor Doped Barium Titanate Ceramics
AU - Hofer, Johannes
N1 - no embargo
PY - 2016
Y1 - 2016
N2 - In this work net-donor doped barium titanate ceramics were studied with impedance spectroscopy in the temperature range of 50 – 400 °C, SEM-EDX, XRD and TG-MS. A modified solid oxide route was applied to synthesize disk like ceramic samples showing a micro-scale microstructure and the PTCR-effect. PTCR-curves were measured with impedance spectroscopy, which led to a good separation of bulk-resistivities, grain boundary-resistivities and grain boundary capacitances. A variation of the DC-bias and the AC-amplitude showed the dependence of the electrical resistance of the samples on the applied electric field. Impedance spectroscopy was also applied on industrial PTCR ceramic samples. A variation of DC-bias, AC-amplitude, geometry, sinter-parameters, pO2 and reduction-oxidation experiments led to further insight to the characteristics of the material. The last part of the work dealt with the synthesis of submicron ceramic samples via a nanoscale precursor obtained by an oxalate precipitation route and low temperature calcination. This product was characterized in a temperature range of 50 – 400 °C. No PTCR-effect could be found in this oxalate-precursor product. However, the trapping energy for the Manganese dopant could be determined.
AB - In this work net-donor doped barium titanate ceramics were studied with impedance spectroscopy in the temperature range of 50 – 400 °C, SEM-EDX, XRD and TG-MS. A modified solid oxide route was applied to synthesize disk like ceramic samples showing a micro-scale microstructure and the PTCR-effect. PTCR-curves were measured with impedance spectroscopy, which led to a good separation of bulk-resistivities, grain boundary-resistivities and grain boundary capacitances. A variation of the DC-bias and the AC-amplitude showed the dependence of the electrical resistance of the samples on the applied electric field. Impedance spectroscopy was also applied on industrial PTCR ceramic samples. A variation of DC-bias, AC-amplitude, geometry, sinter-parameters, pO2 and reduction-oxidation experiments led to further insight to the characteristics of the material. The last part of the work dealt with the synthesis of submicron ceramic samples via a nanoscale precursor obtained by an oxalate precipitation route and low temperature calcination. This product was characterized in a temperature range of 50 – 400 °C. No PTCR-effect could be found in this oxalate-precursor product. However, the trapping energy for the Manganese dopant could be determined.
KW - Donor doped barium titanate
KW - Impedance spectroscopy
KW - PTC-effect
KW - Interfacially controlled electroceramics
KW - Grain boundaries
KW - Electrical properties
KW - Nanosynthesis
KW - Oxalate route
KW - Solid oxid route
KW - Donor dotiertes Bariumtitanat
KW - Impdedanzspektroskopie
KW - PTC-Effekt
KW - Grenzflächenkontrollierte Elektrokeramiken
KW - Korngrenzen
KW - Elektrische Eigenschaften
KW - Nanosynthese
KW - Oxalat-Route
KW - Festoxid Route
M3 - Doctoral Thesis
ER -