The performance of superconducting qubits is often limited by dissipation and two-level systems (TLS) losses. The dominant sources of these losses are believed to originate from amorphous materials and defects at interfaces and surfaces, likely as a result of fabrication processes or ambient exposure. Here, we explore a novel wet chemical surface treatment at the Josephson junction-substrate and the substrate-air interfaces by replacing a buffered oxide etch (BOE) cleaning process with one that uses hydrofluoric acid followed by aqueous ammonium fluoride. We show that the ammonium fluoride etch process results in a statistically significant improvement in median T1 by ∼22% (p=0.002), and a reduction in the number of strongly-coupled TLS in the tunable frequency range. Microwave resonator measurements on samples treated with the ammonium fluoride etch prior to niobium deposition also show ∼33% lower TLS-induced loss tangent compared to the BOE treated samples. As the chemical treatment primarily modifies the Josephson junction-substrate interface and substrate-air interface, we perform targeted chemical and structural characterizations to examine materials' differences at these interfaces and identify multiple microscopic changes that could contribute to decreased TLS.
@article{arxiv.2408.02863,
title = {Enhanced Superconducting Qubit Performance Through Ammonium Fluoride Etch},
author = {Cameron J. Kopas and Dominic P. Goronzy and Thang Pham and Carlos G. Torres Castanedo and Matthew Cheng and Rory Cochrane and Patrick Nast and Ella Lachman and Nikolay Z. Zhelev and Andre Vallieres and Akshay A. Murthy and Jin-su Oh and Lin Zhou and Matthew J. Kramer and Hilal Cansizoglu and Michael J. Bedzyk and Vinayak P. Dravid and Alexander Romanenko and Anna Grassellino and Josh Y. Mutus and Mark C. Hersam and Kameshwar Yadavalli},
journal= {arXiv preprint arXiv:2408.02863},
year = {2025}
}