Joining of alumina via copper/niobium/copper interlayers

Alumina has been joined at 1150 degreesC and 1400 degreesC using multilayer copper/niobium/copper interlayers. Four-point bend strengths are sensitive to processing temperature, bonding pressure, and furnace environment (ambi ent oxygen partial pressure). Under optimum conditions, joints with reprodu cibly high room temperature strengths (approximate to 240+/-20 MPa) can be produced; most failures occur within the ceramic. Joints made with sapphire show that during bonding an initially continuous copper film undergoes a m orphological instability, resulting in the formation of isolated copper-ric h droplets/particles at the sapphire/interlayer interface, and extensive re gions of direct bonding between sapphire and niobium. For optimized alumina bonds, bend tests at 800-1100 degreesC indicate significant strength is re tained; even at the highest test temperature, ceramic failure is observed. Post-bonding anneals at 1000 degreesC in vacuum or in gettered argon were u sed to assess joint stability and to probe the effect of ambient oxygen par tial pressure on joint characteristics. Annealing in vacuum for up to 200 h causes no significant decrease in room temperature bend strength or change in fracture path. With increasing anneal time in a lower oxygen partial pr essure environment, the fracture strength decreases only slightly, but the fracture path shifts from the ceramic to the interface. (C) 2000 Acta Metal lurgica Inc. Published by Elsevier Science Ltd. All rights reserved.