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Thermocompression bonding technology for multilayer superconducting quantum circuits

C. McRae, Jérémy H. Béjanin, Z. Pagel, A. Abdallah, T. McConkey, C. T. Earnest, J. Rinehart, M. Mariantoni·May 6, 2017·DOI: 10.1063/1.5003169
PhysicsMaterials Science

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Abstract

Extensible quantum computing architectures require a large array of quantum bits operating with low error rates. A quantum processor based on superconducting devices can be scaled up by stacking microchips that perform wiring, shielding, and computational functionalities. In this article, we demonstrate a vacuum thermocompression bonding technology that utilizes thin indium films as a welding agent to attach pairs of lithographically patterned chips. At 10 mK, we find a specific dc bond resistance of 49.2 μΩ cm2. We show good transmission up to 6.8 GHz in a tunnel-capped, bonded device as compared to a similar uncapped device. Finally, we fabricate and measure a set of tunnel-capped superconducting resonators, demonstrating that our bonding technology can be used in quantum computing applications.

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