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The objective of this study is to investigate the effect of reducing environment on the mechanical properties of a joint between a glass-ceramic sealant and an interconnect steel. A technique is developed for measuring the joint strength between glass-ceramic and metallic interconnect under tensile or shear loading in reducing environment at room temperature and 800 ^oC. The applied materials are a GC-9 glass-ceramic developed at the Institute of Nuclear Energy Research (INER) and a commercial Crofer 22 H ferritic stainless steel. Comparison of oxidizing and reducing environment effects on mechanical properties of a joint are also presented for variously, thermally aged conditions.   

Both tensile and shear joint strengths are increased at room temperature and decreased at 800 ^oC after a reducing aging treatment. A reducing aging treatment at 800 ^oC for 1000 h enhances the joint strength of shear loading at room temperature by 24% and degrades it at 800 ^oC by 19%. A reducing aging treatment at 800 ^oC for 1000 h increases the joint strength of tensile loading at room temperature by 47% and deterioriates it at 800 ^oC by 51%. Promotion of joint strength at room temperature may be related to changes in the flaw size and morphology, relaxation of residual stresses, and a greater extent of crystallization during aging treatment. Degradation of joint strength at 800 ^oC is probably due to formation of micro-voids between crystalline and glassy phases after aging treatment.

Through fractography anaysis, fracture mode of the joint is correlated with the measured fracture strength. Four types of fracture modes are identified for the joint specimens. Firstly, fracture occurs within the glass-ceramic layer. Secondly, delamination takes place at the interface between the GC-9 glass-ceramic sealant and a chromate layer. Thirdly, delamination occurs at the interface between the metal substrate and a Cr₂O₃ layer. Fourthly, fracture involves cracking in the interfacial mixed layer of glass-ceramic/chromate/chromia. A greater joint strength is accompanied by cracking within the glass-ceramic layer, while a lower joint strength corresponds to fracture involving interfacial delamination or cracking in the interfacial mixed layer of glass-ceramic/chromate/chromia.

The joint strength and fracture mode are comparable between the given reducing and oxidizing environments for non-aged specimens. Thermal aging treatments in both given environments have detrimental effects on the joint strength at 800 ¢XC. Compared to the shear strength of the non-aged specimens, 19% of reduction in strength is both observed for the specimens exposed to the given reducing and oxidizing environments.