Related papers: Qubit-compatible substrates with superconducting through-silicon vias

Qubit-compatible substrates with superconducting through-silicon vias

URL: http://arxiv.org/abs/2201.10425v3
Date: Tue, 8 Nov 2022 13:01:04 GMT
Title: Qubit-compatible substrates with superconducting through-silicon vias
Authors: K. Grigoras, N. Yurttag\"ul, J.-P. Kaikkonen, E. T. Mannila, P. Eskelinen, D. P. Lozano, H.-X. Li, M. Rommel, D. Shiri, N. Tiencken, S. Simbierowicz, A. Ronzani, J. H\"atinen, D. Datta, V. Vesterinen, L. Gr\"onberg, J. Bizn\'arov\'a, A. Fadavi Roudsari, S. Kosen, A. Osman, M. Prunnila, J. Hassel, J. Bylander, J. Govenius
Abstract summary: We characterize superconducting vias and electrodes suitable for superconducting quantum processors. We measure internal quality factors of a million for test resonators excited at single-photon levels. Via stitching of ground planes is an important enabling technology for increasing the physical size of quantum processor chips.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We fabricate and characterize superconducting through-silicon vias and electrodes suitable for superconducting quantum processors. We measure internal quality factors of a million for test resonators excited at single-photon levels, on chips with superconducting vias used to stitch ground planes on the front and back sides of the chips. This resonator performance is on par with the state of the art for silicon-based planar solutions, despite the presence of vias. Via stitching of ground planes is an important enabling technology for increasing the physical size of quantum processor chips, and is a first step toward more complex quantum devices with three-dimensional integration.

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