Synthesis and Characterization of Bismuth Borate-Barium Titanate Glass Ceramics

Objectives: In the present investigation, transparent novel glass embedded with ferroic matrix was prepared by melt-quenching method.Among all the glasses, selective glass ceramic is also prepared.Optical and electrical measurements were carried out on the samples.Methods: We have prepared the transparent glass composition of (100-x)[0.55Bi 2 O 3 -0.30B 2 O 3 -0.15TiO 2 ] +xBaTiO 3 , with x=0, 10, 20, 30, 40, 50 wt.%.Appropriate amounts of reactant mixture were well mixed in agate mortar and melted in a porcelain crucible.The composition is quickly quenched by pouring on pre-heated stainless-steel plate and pressed with another plate.Differential Thermal Analysis was made on the glasses.Detailed optical absorption and impedance measurements were made on the said above glass matrix.Findings: From the XRD spectra, amorphous and crystalline nature was established on the glass and glass ceramic sample.Optical absorption spectra show that with increasing the BaTiO 3 in the glass matrix, it results into structural compactness by means of non-bridging oxygen.The results are consistent with the oxygen packing density values.Impedance spectroscopic plots have shown broad peaks and therefore these materials are being considered as special type multicomponent glass ceramics.Disorder nature of the samples was also discussed with the help of dc-conductivity plots.Among all the samples, 60-BBT-40BT has shown broad spectroscopic peak.Therefore, this sample was annealed at 700 o C, and the XRD pattern resembles with Bi 4 Ti 3 O 12 Aurivillius phase, instead of BaTiO 3 phase.Detailed impedance measurements were also made on the glass ceramic.Novelty: Dielectric ceramic-glass are being used to fabricate energy storage capacitors; however, further studies are needed in order to improve pore-free microstructures.In view of this, transparent glass matrices are embedded with ferroic materials namely BaTiO 3 and the combined optical and electrical results would be useful for future promising optoelectronic materials by means of oneto-many applications.