Reducing dissipation for superconducting qubits

Nasser Alidoust; Ani Nersisyan; Stefano Poletto; Riccardo Manenti; Russ Renzas; Eyob A Sete; Catvu Bui; Kim Vu; Tyler Whyland; Yuvraj Mohan; Sam Stanwyck; Jayss Marshall; Kamal Yadav; Andrew Bestwick; Matthew J Reagor

Reducing dissipation for superconducting qubits

ORAL

Abstract

Extending qubit lifetimes (T₁, T₂) remains a core challenge in developing large-scale quantum computers with superconductors. In this talk, we discuss a variety of substrate cleaning and subtractive patterning techniques responsible for increasing T₁ for superconducting qubits. For these analyses, we have developed fabrication flows based on subtractively-patterned niobium that yield resonators with average internal quality factors of Q_int ≈ 1×10⁶ across several wafers and chips. We show options for integrating Josephson junctions into these process flows to make functional qubits with high coherence times.

^*Work at the Molecular Foundry was supported by the Office of Science, Office of Basic Energy Sciences, of the U.S. Department of Energy under Contract No. DE-AC02-05CH11231.

March 6, 2019, 10:12 AM – March 6, 2019, 10:24 AM

Presenters

Nasser Alidoust
- Rigetti Computing

Authors

Nasser Alidoust
- Rigetti Computing
Ani Nersisyan
- Rigetti Computing
Stefano Poletto
- Rigetti Computing
Riccardo Manenti
- Rigetti Computing
Russ Renzas
- Rigetti Computing
Eyob A Sete
- Rigetti Computing
Catvu Bui
- Rigetti Computing
Kim Vu
- Rigetti Computing
Tyler Whyland
- Rigetti Computing
Yuvraj Mohan
- Rigetti Computing
Sam Stanwyck
- Rigetti Computing
Jayss Marshall
- Rigetti Computing
Kamal Yadav
- Rigetti Computing
Andrew Bestwick
- Rigetti Computing
Matthew J Reagor
- Rigetti Computing