Ultrathin TaN Damascene Nanowire Structures on 300-mm Si Wafers for Quantum Applications

Ekta Bhatia; Jack Lombardi; Soumen Kar; Michael Senatore; Stephen Olson; Tuan Vo; Sandra Schujman; Jakub Nalaskowski; Hunter Frost; John Mucci; Brian Martinick; Pui Yee Hung; Ilyssa Wells; Thomas Murray; Corbet S. Johnson; Aleksandra Biedron; Vidya Kaushik; Dan Campbell; Matthew D. Lahaye; Satyavolu S. Papa Rao

doi:10.1109/TQE.2023.3289257

IEEE Transactions on Quantum Engineering (Jan 2023)

Ultrathin TaN Damascene Nanowire Structures on 300-mm Si Wafers for Quantum Applications

Ekta Bhatia,
Jack Lombardi,
Soumen Kar,
Michael Senatore,
Stephen Olson,
Tuan Vo,
Sandra Schujman,
Jakub Nalaskowski,
Hunter Frost,
John Mucci,
Brian Martinick,
Pui Yee Hung,
Ilyssa Wells,
Thomas Murray,
Corbet S. Johnson,
Aleksandra Biedron,
Vidya Kaushik,
Dan Campbell,
Matthew D. Lahaye,
Satyavolu S. Papa Rao

Affiliations

Ekta Bhatia: ORCiD; NY CREATES, Albany, NY, USA
Jack Lombardi: United States Air Force Research Laboratory, Rome, NY, USA
Soumen Kar: ORCiD; NY CREATES, Albany, NY, USA
Michael Senatore: United States Air Force Research Laboratory, Rome, NY, USA
Stephen Olson: NY CREATES, Albany, NY, USA
Tuan Vo: NY CREATES, Albany, NY, USA
Sandra Schujman: ORCiD; NY CREATES, Albany, NY, USA
Jakub Nalaskowski: NY CREATES, Albany, NY, USA
Hunter Frost: ORCiD; College of Nanoscale Science and Engineering, SUNY Polytechnic Institute, Albany, NY, USA
John Mucci: NY CREATES, Albany, NY, USA
Brian Martinick: NY CREATES, Albany, NY, USA
Pui Yee Hung: NY CREATES, Albany, NY, USA
Ilyssa Wells: NY CREATES, Albany, NY, USA
Thomas Murray: NY CREATES, Albany, NY, USA
Corbet S. Johnson: NY CREATES, Albany, NY, USA
Aleksandra Biedron: NY CREATES, Albany, NY, USA
Vidya Kaushik: NY CREATES, Albany, NY, USA
Dan Campbell: United States Air Force Research Laboratory, Rome, NY, USA
Matthew D. Lahaye: ORCiD; United States Air Force Research Laboratory, Rome, NY, USA
Satyavolu S. Papa Rao: ORCiD; NY CREATES, Albany, NY, USA

DOI: https://doi.org/10.1109/TQE.2023.3289257
Journal volume & issue: Vol. 4
pp. 1 – 8

Abstract

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We report on the development and characterization of superconducting damascene tantalum nitride (TaN) nanowires, 100 nm–3 μm wide, with TaN thicknesses varying from 5 to 35 nm, using 193-nm optical lithography and chemical mechanical planarization among other 300-mm wafer-scale processes. The TaN film composition chosen for nanowire fabrication was informed by a detailed study of unpatterned TaN films with varying nitrogen to tantalum ratios, formed by reactive sputtering. We also discuss the influence of encapsulation by copper and disordered atomic layer deposited TaN on the critical current of superconducting nanowires. Superconducting critical current density (measured at 12 mK) ranges from 0.12 to 0.85 MA/cm2 depending on nanowire width and film thickness. The potential of ultrathin TaN nanowires at 300-mm scale is discussed in the context of applications such as on-chip integration for readout of superconducting qubits, in single-photon detection for quantum computing, as well as in large single-photon detecting focal plane arrays for cosmology in a broader range of wavelengths.

Published in IEEE Transactions on Quantum Engineering

ISSN: 2689-1808 (Online)
Publisher: IEEE
Country of publisher: United States
LCC subjects: Science: Physics: Atomic physics. Constitution and properties of matter; Technology: Electrical engineering. Electronics. Nuclear engineering: Materials of engineering and construction. Mechanics of materials
Website: https://ieeexplore.ieee.org/xpl/RecentIssue.jsp?punumber=8924785

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