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Thoen, David
SRON Netherlands Institute for Space Research
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (10/10 displayed)
- 2022Model and Measurements of an Optical Stack for Broadband Visible to Near-Infrared Absorption in TiN MKIDscitations
- 2022Hydrogenated Amorphous Silicon Carbidecitations
- 2021Highly-conformal sputtered through-silicon vias with sharp superconducting transitioncitations
- 2021Highly-conformal sputtered through-silicon vias with sharp superconducting transitioncitations
- 2021Superconducting Microstrip Losses at Microwave and Submillimeter Wavelengthscitations
- 2020Fabrication of Al-based superconducting high-aspect ratio TSVs for quantum 3D integrationcitations
- 2020Fabrication of Al-based superconducting high-aspect ratio TSVs for quantum 3D integrationcitations
- 2017Reactive Magnetron Sputter Deposition of Superconducting Niobium Titanium Nitride Thin Films with Different Target Sizescitations
- 2017Performance of THz Components Based on Microstrip PECVD SiNx Technologycitations
- 2016Branchline and directional THz coupler based on PECVD SiNx-technologycitations
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article
Reactive Magnetron Sputter Deposition of Superconducting Niobium Titanium Nitride Thin Films with Different Target Sizes
Abstract
<p>The superconducting critical temperature (T-{c} > 15 K) of niobium titanium nitride (NbTiN) thin films allows for low-loss circuits up to 1.1 THz, enabling on-chip spectroscopy and multipixel imaging with advanced detectors. The drive for large-scale detector microchips is demanding NbTiN films with uniform properties over an increasingly larger area. This paper provides an experimental comparison between two reactive dc sputter systems with different target sizes: A small target (o100 mm) and a large target (127 mm × 444.5 mm). This paper focuses on maximizing the T-{c} of the films and the accompanying I-V characteristics of the sputter plasma, and we find that both systems are capable of depositing films with T-{c} > 15 K. The resulting film uniformity is presented in a second manuscript in this volume. We find that these films are deposited within the transition from metallic to compound sputtering, at the point where target nitridation most strongly depends on nitrogen flow. Key in the deposition optimization is to increase the system's pumping speed and gas flows to counteract the hysteretic effects induced by the target size. Using the I-V characteristics as a guide proves to be an effective way to optimize a reactive sputter system, for it can show whether the optimal deposition regime is hysteresis-free and accessible.</p>