Micro solid oxide fuel cells (μ-SOFCs) based on MEMS fabrication processes have become an increasingly attractive development for portable power generation applications, due to their high power density and their compatibility with hydrocarbon fuels. For system packaging, the silicon-based fuel cell membrane module needs to be integrated together with other functional elements such as the gas processing unit and the post-combustor. Silicon wafer bonding techniques can be utilized to avoid thermo-mechanical stresses, however, the complete integration in silicon technology is very challenging; ceramic carriers combined with thick film technology are much more practical for total integration, but exist other challenges. As ceramics may have a slight thermal mismatch with silicon, hermetic assembly by glass sealing can be problematic due to stress build-up. Moreover, the high necessary sealing temperatures are somewhat beyond the survival conditions of the current fuel cell modules. Therefore, a metallic thick-film silver die-attach approach is proposed as a potential bonding solution, due to its flexible fabrication requirements, the relatively low process temperatures and the high ductility and chemical stability of silver materials. Such a seal could potentially compensate the thermal mismatch between the silicon and the ceramic substrate as well as provide reasonable hermeticity under μ-SOFC operating conditions. In this work, we preliminarily evaluated several commercial thick-film silver products as interconnection materials in terms of mechanical strength, firing process and metallization approach, using shear testing and microstructure characterization. The failure mode of the die-attach was discussed in details and related to their bonding mechanism. The influence of firing temperature and additional prior metallization on those thick-film bonds were also studied.
Rapid Thermal-Cycling Test Using Thick-Film Electrolyte-Supported Solid Oxide Fuel Cells
