English

Pseudo-2D superconducting quantum computing circuit for the surface code: the proposal and preliminary tests

Quantum Physics 2020-06-24 v3

Abstract

Of the many potential hardware platforms, superconducting quantum circuits have become the leading contender for constructing a scalable quantum computing system. All current architecture designs necessitate a 2D arrangement of superconducting qubits with nearest neighbour interactions, compatible with powerful quantum error correction using the surface code. A major hurdle for scalability in superconducting systems is the so called wiring problem, where qubits internal to a chip-set become inaccessible for external control/readout lines. Current approaches resort to intricate and exotic 3D wiring and packaging technology which is a significant engineering challenge to realize, while maintaining qubit fidelity. Here we solve this problem and present a modified superconducting scalable micro-architecture that does not require any 3D external line technology and reverts back to a completely planar design. This is enabled by a new pseudo-2D resonator network that provides inter-qubit connections via airbridges. We carried out experiments to examine the feasibility of the newly introduced airbridge component. The measured quality factor of these new inter-qubit resonators is sufficient for high fidelity gates, below the threshold for the surface code, with negligible measured cross-talk. The resulting physical separation of the external wirings and the inter-qubit connections on-chip should reduce cross-talk and decoherence as the chip-set increases in size. This result demonstrates that a large-scale, fully error corrected quantum computer can be constructed by monolithic integration technologies without additional overhead and without special packaging know-hows.

Keywords

Cite

@article{arxiv.1902.07911,
  title  = {Pseudo-2D superconducting quantum computing circuit for the surface code: the proposal and preliminary tests},
  author = {H. Mukai and K. Sakata and S. J. Devitt and R. Wang and Y. Zhou and Y. Nakajima and J. S. Tsai},
  journal= {arXiv preprint arXiv:1902.07911},
  year   = {2020}
}

Comments

8 pages, 7 figures

R2 v1 2026-06-23T07:46:49.957Z