Master Degree / Yüksek Lisans Tezleri
Permanent URI for this collectionhttps://hdl.handle.net/11147/3008
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Master Thesis Ferroelectric Ceramic Polymer Nanocomposites for Electrocaloric Cooling Applications(Izmir Institute of Technology, 2020) Tokkan, Melike; Adem, UmutIn this study, nanocomposites consisting of the polymer matrix and nanometer sized ceramic supporting phase were produced for electrocaloric cooling applications, which show potential as alternative refrigerant system. The aim of this study was to be able to estimate adiabatic temperature change (?T) of the composites by measuring saturated hysteresis loops for the composite materials that allow accurate calculation of the ?T using the indirect method based on Maxwell's relations. Ba0.94Ca0.06Ti0.925Sn0.075O3(BCST) composition ceramic was used as the supporting phase of the composite and P(VDF-TrFE)(55-45) co-polymer was chosen as the matrix. The ceramics were synthesized, as pellets by conventional solid-state method. Ferroelectric nanocomposites were manufactured by solution casting method by adding 5, 7.5, 10 volume percent of the ceramic powder, which was obtained by grinding the pellets by using ball milling. Phase analysis of all materials done using X-ray Diffraction method. Fourier Transform Infrared Spectroscopy was used to clearly understand the phase structure of polymer. Scanning electron microscopy was used for understand the distribution of ceramic particles in polymer matrix. Dielectric constant-dielectric loss and ferroelectric hysteresis loops were measured as a function of temperature for the electrical characterization of the materials. Adiabatic temperature change under electric field (?T) of the materials were calculated based on Maxwell's equations indirectly using the temperature dependent electrical polarization data. The dielectric constant and electrical polarization of the polymer matrix have increased with the addition of ceramic particles. The hysteresis loops of thebn pure polymer and composites were saturated, therefore the temperature change can be calculated accurately with the indirect method. Maximum ?T was calculated on the composite having 10vol% ceramic particles. (6.964K at 900 kV/cm).Master Thesis Batio3 Based Ferroelectric Materials for Electrocaloric Cooling Applications(Izmir Institute of Technology, 2018) Şanlı, Keriman; Adem, Umut; Akdoğan, YaşarThe aim of this project was to produce electrocaloric materials and to determine the potential of these materials for electrocaloric cooling applications. The electrocaloric effect (ECE) of lead-free Ba0.8Sr0.2Ti1-xZrxO3 (0 ≤ x ≤ 0.10) ferroelectric ceramics was studied. The phase analysis of each ceramic composition that was synthesized by conventional solid-state reaction technique was performed by X-ray Diffraction. Dielectric measurements were done to determine the phase transition temperatures (Curie temperature, Tc) of all compositions and also construct a phase diagram. ΔT values were calculated indirectly using electrical polarization curves measured at different temperatures and Maxwell's equations. ΔT values that were obtained from different regions of the phase diagram are compared. The most suitable composition for applications was chosen considering the ΔT value, temperature range where relatively large ΔT is preserved and the Curie temperature of all ceramics. Ba0.8Sr0.2Ti0.93Zr0.07O3 ceramic located near the critical point shows the best performance with ΔT value of 0.40 K under 20 kV/cm. In comparison with the lead-free ceramics studied in the literature, Ba0.8Sr0.2Ti1-xZrxO3 system can be considered as one of the best candidates for future electrocaloric cooling technologies.