Zirconia-based materials in alternative energy devices-A strategy for improving material properties by optimizing the characteristics of initial powders

This work is devoted to the demonstration of a real multifunctional material -zirconia based nanopowders, which can be used in the manufacture of various types of devices that convert natural energy sources into electricity (electrolyte and anode for SOFC, moisture-to-electricity converter). It was shown that such characteristics of nanopowders as parti-cle size, specific surface area, and type of surface centers, which depend on the temper-ature of nanopowder synthesis, could play both a positive and a negative role in the formation of the functional properties of a device. It was found that the synthesis of 8YSZ nanopowders at 700 degrees C is optimal for the manufacture of a dense electrolyte material and a porous SOFC anode material during sintering at 1400-1450 degrees C. The addition of a small amount of Al2O3 at the synthesis stage accelerates the sintering of the SOFC electrolyte material by 120 degrees C and leads to increasing the density to 97% of the theoretical value. The strength of the sintered anode material practically does not change after reduction in an atmosphere of N2-10% H2-5% CO2 and the value is 100 MPa. The synthesis temperature of 8YSZ nanopowder at 700 degrees C is also optimal for the manufacture of porous converters of ambient humidity into electricity. The formation of particles with a given size and type of surface centers allows generating an electric po- tential (100-200 mV) for hundreds of hours, which is 2-3 times higher than that of larger and smaller powders. The result of the work show that there are optimal conditions for the synthesis of powders (synthesis method, additives, synthesis temperature), as a result of which nanopowders are formed with characteristics (particle size, specific surface area, morphology) necessary and sufficient for the manufacture of several types of materials for devices of alternative energy. (c) 2021 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.