Modern Materials Engineering for High-Fidelity and Manufacturable Superconducting Qubits

Jake Rochman; Haoxiong Yan; Yue Chen; Lei Jiang; Wenhui Wang; Zihao Yang; Ruoyu Li; Leslie Du; Zhebo Chen; Mingwei Zhu; Nag Patibandla; Robert Visser

Modern Materials Engineering for High-Fidelity and Manufacturable Superconducting Qubits

ORAL

Abstract

Superconducting qubits are a promising platform for fault-tolerant quantum computers. Although there have been significant developments over the years, superconducting qubit hardware is currently limited by the qubit error rates and number of qubits. Error rates for superconducting qubits are typically dominated by material interface losses and defects.

Over the past decade, advanced CMOS manufacturing on 300 mm wafers has enabled significant innovation in the semiconductor industry for classical computing hardware. Superconducting qubit technology can leverage the capabilities developed for the semiconductor industry to improve qubit performance. In this talk, we present initial results towards fabricating superconducting qubits with improved interfaces using modern CMOS materials engineering methods.

March 17, 2025, 6:00 PM – March 17, 2025, 6:12 PM

Presenters

Jake Rochman

Applied Materials

Authors

Jake Rochman

Applied Materials
Haoxiong Yan

Applied Materials, University of Chicago
Yue Chen

Applied Materials
Lei Jiang

Applied Materials
Wenhui Wang

Applied Materials
Zihao Yang

Applied Materials
Ruoyu Li

IMEC, Applied Materials
Leslie Du

Applied Materials
Zhebo Chen

Applied Materials
Mingwei Zhu

Applied Materials
Nag Patibandla

Applied Materials
Robert Visser

Applied Materials