Related papers: Superconducting-semiconducting voltage-tunable qubits in the third dimension

Superconducting-semiconducting voltage-tunable qubits in the third dimension

URL: http://arxiv.org/abs/2203.06209v1
Date: Fri, 11 Mar 2022 19:03:23 GMT
Title: Superconducting-semiconducting voltage-tunable qubits in the third dimension
Authors: Thomas M. Hazard, Andrew J. Kerman, Kyle Serniak and Charles Tahan
Abstract summary: Super-semiconducting (super-semi) qubit and coupler designs based on high-quality, compact through-silicon vias (TSVs) An interposer "probe" wafer containing TSVs is used to contact a sample wafer with, for example, a superconductor-proximitized, epitaxially-grown, germanium quantum well. We show how this approach shrinks the on-chip footprint of voltage-tunable superconducting qubits and promises to accelerate the understanding of super-semi heterostructures in a variety of systems.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We propose superconducting-semiconducting (super-semi) qubit and coupler designs based on high-quality, compact through-silicon vias (TSVs). An interposer "probe" wafer containing TSVs is used to contact a sample wafer with, for example, a superconductor-proximitized, epitaxially-grown, germanium quantum well. By utilizing the capacitance of the probe wafer TSVs, the majority of the electric field in the qubits is pulled away from lossy regions in the semiconducting wafer. Through simulations, we find that the probe wafer can reduce the qubit's electric field participation in the sample wafer by an order of magnitude for thin substrates and remains small even when the epitaxial layer thickness approaches 100 $\mu$m. We also show how this scheme is extensible to multi-qubit systems which have tunable qubit-qubit couplings without magnetic fields. This approach shrinks the on-chip footprint of voltage-tunable superconducting qubits and promises to accelerate the understanding of super-semi heterostructures in a variety of systems.

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