Διεπιφανειακές ιδιότητες συστημάτων κεραμικών οξειδίων (δομικών και λειτουργικών) σε επαφή με ρευστές φάσεις

Abstract

Advanced ceramics (structural or functional) are considered to be the most suitable for use in high temperature applications. They have a number of advantages, such as resistance to thermal shocks, high hardness, wear and corrosion resistance and a wide range in the values of their electrical properties. Special interest is being manifested in the compounds of ceramics with metals and metal alloys, in the field of materials joining and the production of composite materials. Ceramic compounds are used in the field of solid oxide fuel cells (SOFC) as insulators and sealing materials. Particular interest has been stimulated in the interaction in the interface of ceramics in contact with liquid silver and silver based alloys, as alternatives to the glass-ceramics sealing materials in SOFC stacks. In all of these cases the surface and interfacial energies of the materials or the materials systems used, as well as the wetting and bonding phenomena at the interface, play a key role in obtaining materials with the desired properties and microstructure. The aim of the present work is the study of adhesion and interfacial properties in ceramic oxide / liquid metal systems, particularly in systems of ceramic oxides in contact with liquid silver and silver-based alloys, with the ultimate aim of implementing such systems in the SOFC technology. In the first part of this work, the effect of the dissoluted oxygen on the surface energy of liquid copper and liquid silver was examined. The equations that were deriverd can be used to calculate their surface energy as a function of the temperature and the partial pressure of the oxygen. The free energy of the oxygen adsorption in the surface of the liquid copper was calculated, until saturation. Also, an equation that allows to calculate the solubility of an oxide in a liquid metal was deriverd, as a function of the temperature and the oxygen partial pressure. Moreover, from the combination of literature and experimental data of interfacial energies and contact angles in non-wetting and non-reactive ceramic oxide/liquid metal systems where the limited solubility of oxygen of the ceramic oxides into the liquid metalls has no effect on the interfacial properties, has led to an empirical relationship which correlates at a given temperature the surface energy of the oxides with the contact angle and the surface energy of the liquid metal. This relationship allows either the calculation of the surface energy of an oxide from known values of the surface energy of a liquid metal and the contact angle, or conversely, the estimation of the contact angle value, as well as the work of adhesion, for known surface energy of the oxide. The formulated empirical relationship has been applied to additional non-wetting and non-reactive systems of oxides in contact with liquid metals and the results showed good agreement with literature data. In addition, the empirical formula was used to calculate the surface energies of the polycrystalline oxides Y2O3 and 3YTZ (3mol% Yttria partial stabilized zirconia) as well as the 85wt% MgO + 15 wt% MgAl2O4 mixed oxide, after wetting experiments with liquid copper and/or liquid silver in an Ar- 4%H2 atmosphere. In the second part of this work, the effect of the oxygen on the the interfacial properties of the ceramics / liquid silver systems was examined by wetting experiments, in order to achieve conditions similar to the SOFC operating conditions. The results showed that the presence of the oxygen improves the wetability in the ceramic / liquid metal systems, increasing the bond in the interface but the angle remains θ > 90◦ (non wetting systems). The addition of interfacial active compounds in the liquid metal led to a significant decrease in the contact angle value, with the simultaneous increase in the work of adhesion, and so to the increase in the strength of the bond. For this purpose and in order to examine the adhesion between the two phases, wetting experiments with lithium and borium based oxides took place. Finally, the above liquid phases were used in wetting experiments on steel substrate (Crofer 22 APU) in order to investigate the potential usage of them as sealing and insulators in SOFC technology.