Systematic Improvements in Transmon Qubit Coherence Enabled by Niobium Surface Encapsulation

TL;DR

This paper introduces a niobium surface encapsulation technique that significantly enhances transmon qubit coherence times by preventing lossy oxide formation, achieving record-breaking lifetimes on sapphire and silicon substrates.

Contribution

It demonstrates a novel surface passivation method for niobium that improves qubit coherence, surpassing previous lifetimes and offering scalable fabrication advantages.

Findings

Niobium oxides reduce qubit coherence compared to other oxides.

Encapsulation with tantalum yields median T1 times above 300 microseconds.

Surface passivation enhances qubit performance and scalability.

Abstract

We present a novel transmon qubit fabrication technique that yields systematic improvements in T$_1$ relaxation times. We fabricate devices using an encapsulation strategy that involves passivating the surface of niobium and thereby preventing the formation of its lossy surface oxide. By maintaining the same superconducting metal and only varying the surface structure, this comparative investigation examining different capping materials, such as tantalum, aluminum, titanium nitride, and gold, and film substrates across different qubit foundries definitively demonstrates the detrimental impact that niobium oxides have on the coherence times of superconducting qubits, compared to native oxides of tantalum, aluminum or titanium nitride. Our surface-encapsulated niobium qubit devices exhibit T$_1$ relaxation times 2 to 5 times longer than baseline niobium qubit devices with native niobium oxides. When capping niobium with tantalum, we obtain median qubit lifetimes above 300 microseconds, with maximum values up to 600 microseconds, that represent the highest lifetimes to date for superconducting qubits prepared on both sapphire and silicon. Our comparative structural and chemical analysis suggests why amorphous niobium oxides may induce higher losses compared to other amorphous oxides. These results are in line with high-accuracy measurements of the niobium oxide loss tangent obtained with ultra-high Q superconducting radiofrequency (SRF) cavities. This new surface encapsulation strategy enables even further reduction of dielectric losses via passivation with ambient-stable materials, while preserving fabrication and scalable manufacturability thanks to the compatibility with silicon processes.