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26 results on '"Kopas, Cameron J."'

1. Enhanced Superconducting Qubit Performance Through Ammonium Fluoride Etch

Author

Kopas, Cameron J., Goronzy, Dominic P., Pham, Thang, Castanedo, Carlos G. Torres, Cheng, Matthew, Cochrane, Rory, Nast, Patrick, Lachman, Ella, Zhelev, Nikolay Z., Vallieres, Andre, Murthy, Akshay A., Oh, Jin-su, Zhou, Lin, Kramer, Matthew J., Cansizoglu, Hilal, Bedzyk, Michael J., Dravid, Vinayak P., Romanenko, Alexander, Grassellino, Anna, Mutus, Josh Y., Hersam, Mark C., and Yadavalli, Kameshwar

Subjects
Condensed Matter - Materials Science, Quantum Physics
Abstract

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 $\text{T}_1$ by $\sim22\%$ ($p=0.002$), 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 $\sim33\%$ 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.

Published
2024

2. Formation and Microwave Losses of Hydrides in Superconducting Niobium Thin Films Resulting from Fluoride Chemical Processing

Author

Torres-Castanedo, Carlos G., Goronzy, Dominic P., Pham, Thang, McFadden, Anthony, Materise, Nicholas, Das, Paul Masih, Cheng, Matthew, Lebedev, Dmitry, Ribet, Stephanie M., Walker, Mitchell J., Garcia-Wetten, David A., Kopas, Cameron J., Marshall, Jayss, Lachman, Ella, Zhelev, Nikolay, Sauls, James A., Mutus, Joshua Y., McRae, Corey Rae H., Dravid, Vinayak P., Bedzyk, Michael J., and Hersam, Mark C.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Superconductivity, Physics - Applied Physics, Quantum Physics
Abstract

Superconducting Nb thin films have recently attracted significant attention due to their utility for quantum information technologies. In the processing of Nb thin films, fluoride-based chemical etchants are commonly used to remove surface oxides that are known to affect superconducting quantum devices adversely. However, these same etchants can also introduce hydrogen to form Nb hydrides, potentially negatively impacting microwave loss performance. Here, we present comprehensive materials characterization of Nb hydrides formed in Nb thin films as a function of fluoride chemical treatments. In particular, secondary-ion mass spectrometry, X-ray scattering, and transmission electron microscopy reveal the spatial distribution and phase transformation of Nb hydrides. The rate of hydride formation is determined by the fluoride solution acidity and the etch rate of Nb2O5, which acts as a diffusion barrier for hydrogen into Nb. The resulting Nb hydrides are detrimental to Nb superconducting properties and lead to increased power-independent microwave loss in coplanar waveguide resonators. However, Nb hydrides do not correlate with two-level system loss or device aging mechanisms. Overall, this work provides insight into the formation of Nb hydrides and their role in microwave loss, thus guiding ongoing efforts to maximize coherence time in superconducting quantum devices.

Published
2024
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4. Systematic improvements in transmon qubit coherence enabled by niobium surface encapsulation

Author

Bal, Mustafa, Murthy, Akshay A., Zhu, Shaojiang, Crisa, Francesco, You, Xinyuan, Huang, Ziwen, Roy, Tanay, Lee, Jaeyel, Zanten, David van, Pilipenko, Roman, Nekrashevich, Ivan, Lunin, Andrei, Bafia, Daniel, Krasnikova, Yulia, Kopas, Cameron J., Lachman, Ella O., Miller, Duncan, Mutus, Josh Y., Reagor, Matthew J., Cansizoglu, Hilal, Marshall, Jayss, Pappas, David P., Vu, Kim, Yadavalli, Kameshwar, Oh, Jin-Su, Zhou, Lin, Kramer, Matthew J., Lecocq, Florent, Goronzy, Dominic P., Torres-Castanedo, Carlos G., Pritchard, P. Graham, Dravid, Vinayak P., Rondinelli, James M., Bedzyk, Michael J., Hersam, Mark C., Zasadzinski, John, Koch, Jens, Sauls, James A., Romanenko, Alexander, and Grassellino, Anna

Published
2024
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5. Systematic Improvements in Transmon Qubit Coherence Enabled by Niobium Surface Encapsulation

Author

Bal, Mustafa, Murthy, Akshay A., Zhu, Shaojiang, Crisa, Francesco, You, Xinyuan, Huang, Ziwen, Roy, Tanay, Lee, Jaeyel, van Zanten, David, Pilipenko, Roman, Nekrashevich, Ivan, Lunin, Andrei, Bafia, Daniel, Krasnikova, Yulia, Kopas, Cameron J., Lachman, Ella O., Miller, Duncan, Mutus, Josh Y., Reagor, Matthew J., Cansizoglu, Hilal, Marshall, Jayss, Pappas, David P., Vu, Kim, Yadavalli, Kameshwar, Oh, Jin-Su, Zhou, Lin, Kramer, Matthew J., Lecocq, Florent Q., Goronzy, Dominic P., Torres-Castanedo, Carlos G., Pritchard, Graham, Dravid, Vinayak P., Rondinelli, James M., Bedzyk, Michael J., Hersam, Mark C., Zasadzinski, John, Koch, Jens, Sauls, James A., Romanenko, Alexander, and Grassellino, Anna

Subjects
Quantum Physics, Condensed Matter - Materials Science, Condensed Matter - Superconductivity
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.

Published
2023
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6. Anisotropic superconductivity of niobium based on its response to non-magnetic disorder

Author

Tanatar, Makariy A., Torsello, Daniele, Joshi, Kamal R., Ghimire, Sunil, Kopas, Cameron J., Marshall, Jayss, Mutus, Josh Y., Ghigo, Gianluca, Zarea, Mehdi, Sauls, James A., and Prozorov, Ruslan

Subjects
Condensed Matter - Superconductivity, Quantum Physics
Abstract

Niobium is one of the most studied superconductors, both theoretically and experimentally. It is tremendously important for applications, and it has the highest superconducting transition temperature, $T_{c}=9.33$ K, of all pure metals. In addition to power applications in alloys, pure niobium is used for sensitive magneto-sensing, radio-frequency cavities, and, more recently, as circuit metallization layers in superconducting qubits. A detailed understanding of its electronic and superconducting structure, especially its normal and superconducting state anisotropies, is crucial for mitigating the loss of quantum coherence in such devices. Recently, a microscopic theory of the anisotropic properties of niobium with the disorder was put forward. To verify theoretical predictions, we studied the effect of disorder produced by 3.5 MeV proton irradiation of thin Nb films grown by the same team and using the same protocols as those used in transmon qubits. By measuring the superconducting transition temperature and upper critical fields, we show a clear suppression of $T_{c}$ by potential (non-magnetic) scattering, which is directly related to the anisotropic order parameter. We obtain a very close quantitative agreement between the theory and the experiment.

Published
2022
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7. Characterization of Nb films for superconducting qubits using phase boundary measurements

Author

Ryan, Kevin M., Torres-Castanedo, Carlos G., Goronzy, Dominic P., Wetter, David A. Garcia, Reagor, Matthew J, Field, Mark, Kopas, Cameron J, Marshall, Jayss, Bedzyk, Michael J., Hersam, Mark C., and Chandrasekhar, Venkat

Subjects
Condensed Matter - Superconductivity
Abstract

Continued advances in superconducting qubit performance require more detailed understandings of the many sources of decoherence. Within these devices, two-level systems arise due to defects, interfaces, and grain boundaries, and are thought to be a major source of qubit decoherence at millikelvin temperatures. In addition to Al, Nb is a commonly used metalization layer for superconducting qubits. Consequently, a significant effort is required to develop and qualify processes that mitigate defects in Nb films. As the fabrication of complete superconducting qubits and their characterization at millikelvin temperatures is a time and resource intensive process, it is desirable to have measurement tools that can rapidly characterize the properties of films and evaluate different treatments. Here we show that measurements of the variation of the superconducting critical temperature $T_c$ with an applied external magnetic field $H$ (of the phase boundary $T_c - H$) performed with very high resolution show features that are directly correlated with the structure of the Nb films. In combination with x-ray diffraction measurements, we show that one can even distinguish variations quality and crystal orientation of the grains in a Nb film by small but reproducible changes in the measured superconducting phase boundary.

Published
2022
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8. Contactless Excitation of Acoustic Resonance in Insulating Wafers

Author

Zhai, Gan, Xin, Yizhou, Kopas, Cameron J., Lachman, Ella, Field, Mark, Mutus, Josh Y., Cicak, Katarina, Aumentado, Jose, Sung, Zuhawn, and Halperin, William P.

Subjects
Physics - Applied Physics
Abstract

Contactless excitation and detection of high harmonic acoustic overtones in a thin insulator single crystal are described using radio frequency spectroscopy techniques. Single crystal [001] silicon wafer samples were investigated, one side covered with a Nb thin film, the common starting point for fabrication of quantum devices. The coupling between electromagnetic signals and mechanical oscillation is achieved from the Lorentz force generated by an external magnetic field. This method is suitable for any sample with a metallic surface or covered with a thin metal film. High resolution measurements of the temperature dependence of the sound velocity and elastic constants of silicon are reported and compared with known results., Comment: 4 pages, 5 figures

Published
2022
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9. Quasiparticle spectroscopy, transport, and magnetic properties of Nb films used in superconducting transmon qubits

Author

Joshi, Kamal R., Ghimire, Sunil, Tanatar, Makariy A., Datta, Amlan, Oh, Jin-Su, Zhou, Lin, Kopas, Cameron J., Marshall, Jayss, Mutus, Josh Y., Slaughter, Julie, Kramer, Matthew J., Sauls, James A., and Prozorov, Ruslan

Subjects
Condensed Matter - Superconductivity, Quantum Physics
Abstract

Niobium thin films on silicon substrate used in the fabrication of superconducting qubits have been characterized using scanning and transmission electron microscopy, electrical transport, magnetization, quasiparticle spectroscopy, and real-space real-time magneto-optical imaging. We study niobium films to provide an example of a comprehensive analytical set that may benefit superconducting circuits such as those used in quantum computers. The films show outstanding superconducting transition temperature of $T_{c}=9.35$ K and a fairly clean superconducting gap, along with superfluid density enhanced at intermediate temperatures. These observations are consistent with the recent theory of anisotropic strong-coupling superconductivity in Nb. However, the response to the magnetic field is complicated, exhibiting significantly irreversible behavior and insufficient heat conductance leading to thermo-magnetic instabilities. These may present an issue for further improvement of transmon quantum coherence. Possible mitigation strategies are discussed.

Published
2022
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10. Simple coplanar waveguide resonator mask targeting metal-substrate interface

Author

Kopas, Cameron J., Lachman, Ella, McRae, Corey Rae H., Mohan, Yuvraj, Mutus, Josh Y., Nersisyan, Ani, and Poudel, Amrit

Subjects
Quantum Physics, Physics - Applied Physics
Abstract

This white paper presents a single-layer mask, found at https://github.com/Boulder-Cryogenic-Quantum-Testbed/simple-resonator-mask. It is designed for fabrication of superconducting microwave resonators towards 1:1 comparisons of dielectric losses from the metal-substrate interface. Finite-element electromagnetic simulations are used to determine participation ratios of the four major regions of the on-chip devices, as well as to confirm lack of crosstalk between neighboring devices and demonstrate coupling tunability over three orders of magnitude. This mask is intended as an open-source community resource for facilitating precise and accurate comparisons of materials in the single-photon, millikelvin regime.

Published
2022

11. Multi-modal electron microscopy study on decoherence sources and their stability in Nb based superconducting qubit

Author

Oh, Jin-Su, Fang, Xiaotian, Kim, Tae-Hoon, Lynn, Matt, Kramer, Matt, Zarea, Mehdi, Sauls, James A., Romanenko, A., Posen, S., Grassellino, A., Kopas, Cameron J., Field, Mark, Marshall, Jayss, Cansizoglu, Hilal, Mutus, Joshua Y., Reagor, Matthew, and Zhou, Lin

Subjects
Condensed Matter - Materials Science
Abstract

Niobium is commonly used for superconducting quantum systems as readout resonators, capacitors, and interconnects. The coherence time of the superconducting qubits is mainly limited by microwave dissipation attributed to two-level system defects at interfaces, such as the Nb/Si and Nb/air interface. One way to improve the Nb/air interface quality is by thermal annealing, as shown by extensive studies in 3D superconducting radio frequency (SRF) cavities. However, it is unclear how the microstructure and chemistry of the interface structures change during heat treatment. To address this knowledge gap, we comprehensively characterized Nb films deposited on Si wafers by physical vapor deposition, including (1) an Nb film from a transmon and (2) an Nb film without any patterning step, using an aberration-corrected transmission electron microscope. Both Nb films exhibit columnar growth with strong [110] textures. There is a double layer between the Nb film and Si substrate, which are amorphous niobium silicides with different Nb and Si concentrations. After in-situ heating of the heterostructure at 360{\deg}C inside the microscope, the composition of the double layers at the Nb-Si interface remains almost the same despite different thickness changes. The initial amorphous niobium oxide layer on Nb surface decomposes into face-centered cubic Nb nanograins in the amorphous Nb-O matrix upon heating.

Published
2022

12. Exploring the relationship between deposition method, microstructure, and performance of Nb/Si-based superconducting coplanar waveguide resonators

Author

Oh, Jin-Su, Kopas, Cameron J., Marshall, Jayss, Fang, Xiaotian, Joshi, Kamal R., Datta, Amlan, Ghimire, Sunil, Park, Joong-Mok, Kim, Richard, Setiawan, Daniel, Lachman, Ella, Mutus, Joshua Y., Murthy, Akshay A., Grassellino, Anna, Romanenko, Alex, Zasadzinski, John, Wang, Jigang, Prozorov, Ruslan, Yadavalli, Kameshwar, Kramer, Matt, and Zhou, Lin

Published
2024
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13. Low microwave loss in deposited Si and Ge thin-film dielectrics at single-photon power and low temperatures

Author

Kopas, Cameron J., Gonzales, Justin, Zhang, Shengke, Queen, Daniel R., Wagner, Brian, Robinson, Mac, Huffman, James, and Newman, Nate

Subjects
Physics - Applied Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

Our study shows that deposited Ge and Si dielectric thin-films can exhibit low microwave losses at near single-photon powers and sub-Kelvin temperatures ($\approx$40 mK). This low loss enables their use in a wide range of devices, including low-loss coplanar, microstrip, and stripline resonators, as well as layers for device isolation, inter-wiring dielectrics, and passivation in microwave and Josephson junction circuit fabrication. We use coplanar microwave resonator structures with narrow trace widths of 2-16 $\mu \textrm{m}$ to maximize the sensitivity of loss tangent measurements to the interface and properties of the deposited dielectrics, rather than to optimize the quality factor. In this configuration, thermally-evaporated $\approx 1 \mu \textrm{m}$ thick amorphous germanium (a-Ge) films deposited on Si (100) have a single photon loss tangent of $1-2\times10^{-6}$ and, $9 \mu \textrm{m}$-thick chemical vapor deposited (CVD) homoepitaxial Si has a single photon loss tangent of $0.6-2\times 10^{-5}$. Interface contamination limits the loss in these devices.

Published
2020
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14. Formation and Microwave Losses of Hydrides in Superconducting Niobium Thin Films Resulting from Fluoride Chemical Processing.

Author

Torres‐Castanedo, Carlos G., Goronzy, Dominic P., Pham, Thang, McFadden, Anthony, Materise, Nicholas, Masih Das, Paul, Cheng, Matthew, Lebedev, Dmitry, Ribet, Stephanie M., Walker, Mitchell J., Garcia‐Wetten, David A., Kopas, Cameron J., Marshall, Jayss, Lachman, Ella, Zhelev, Nikolay, Sauls, James A., Mutus, Joshua Y., McRae, Corey Rae H., Dravid, Vinayak P., and Bedzyk, Michael J.

Subjects
CHEMICAL processes, QUANTUM computing, QUANTUM information science, DIFFUSION barriers, TRANSMISSION electron microscopy
Abstract

Superconducting niobium (Nb) thin films have recently attracted significant attention due to their utility for quantum information technologies. In the processing of Nb thin films, fluoride‐based chemical etchants are commonly used to remove surface oxides that are known to affect superconducting quantum devices adversely. However, these same etchants can also introduce hydrogen to form Nb hydrides, potentially negatively impacting microwave loss performance. Here, comprehensive materials characterization of Nb hydrides formed in Nb thin films as a function of fluoride chemical treatments is presented. In particular, secondary‐ion mass spectrometry, X‐ray scattering, and transmission electron microscopy reveal the spatial distribution and phase transformation of Nb hydrides. The rate of hydride formation is determined by the fluoride solution acidity and the etch rate of Nb2O5, which acts as a diffusion barrier for hydrogen into Nb. The resulting Nb hydrides are detrimental to Nb superconducting properties and lead to increased power‐independent microwave loss in coplanar waveguide resonators. However, Nb hydrides do not correlate with two‐level system loss or device aging mechanisms. Overall, this work provides insight into the formation of Nb hydrides and their role in microwave loss, thus guiding ongoing efforts to maximize coherence time in superconducting quantum devices. [ABSTRACT FROM AUTHOR]

Published
2024
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16. Unraveling the Connection between Deposition, Microstructure, and Performance of Superconducting Quantum Circuits using Multi-modal Electron Microscopy.

Author

Oh, Jin-Su, Kopas, Cameron J, Marshall, Jayss, Fang, Xiaotian, Joshi, Kamal R, Datta, Amlan, Ghimire, Sunil, Park, Joong-Mok, Kim, Richard, Setiawan, Daniel, Lachman, Ella, Mutus, Joshua Y, Murthy, Akshay A, Grassellino, Anna, Romanenko, Alex, Zasadzinski, John, Wang, Jigang, Prozorov, Ruslan, Yadavalli, Kameshwar, and Kramer, Matt

Published
2024
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17. Quasiparticle Spectroscopy, Transport, and Magnetic Properties of Nb Films Used in Superconducting Qubits

Author

Joshi, Kamal R., primary, Ghimire, Sunil, additional, Tanatar, Makariy A., additional, Datta, Amlan, additional, Oh, Jin-Su, additional, Zhou, Lin, additional, Kopas, Cameron J., additional, Marshall, Jayss, additional, Mutus, Josh Y., additional, Slaughter, Julie, additional, Kramer, Matthew J., additional, Sauls, James A., additional, and Prozorov, Ruslan, additional

Published
2023
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18. In-situ transmission electron microscopy investigation on surface oxides thermal stability of niobium

Author

Oh, Jin-Su, primary, Fang, Xiaotian, additional, Kim, Tae-Hoon, additional, Lynn, Matt, additional, Kramer, Matt, additional, Zarea, Mehdi, additional, Sauls, James A., additional, Romanenko, Alexander, additional, Posen, Sam, additional, Grassellino, Anna, additional, Kopas, Cameron J., additional, Field, Mark, additional, Marshall, Jayss, additional, Cansizoglu, Hilal, additional, Yadavalli, Kameshwar, additional, Mutus, Joshua Y., additional, Reagor, Matthew, additional, and Zhou, Lin, additional

Published
2023
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23. Identifying Possible Two-Level-System Sources in Superconducting Qubit with Advanced Electron Microscopy

Author

Zhou, Lin, primary, Oh, Jin-Su, additional, Fang, Xiaotian, additional, Kim, Tae-Hoon, additional, Kramer, Matt, additional, Romanenko, A, additional, Posen, S, additional, Grassellino, A, additional, Kopas, Cameron J, additional, Field, Mark, additional, Marshall, Jayss, additional, Mutus, Joshua Y, additional, Cansizoglu, Hilal, additional, and Reagor, Matthew, additional

Published
2022
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24. Multi-Modal Electron Microscopy Investigation on Decoherence Sources and Their Stability in Nb Based Superconducting Qubit

Author

Oh, Jin-Su, primary, Fang, Xiaotian, additional, Kim, Tae-Hoon, additional, Lynn, Matt, additional, Kramer, Matt, additional, Zarea, Mehdi, additional, Sauls, James, additional, Romanenko, Alex, additional, Posen, Sam, additional, Grassellino, Anna, additional, Kopas, Cameron J., additional, Field, Mark, additional, Marshall, Jayss, additional, Cansizoglu, Hilal, additional, Mutus, Joshua Y., additional, Reagor, Matthew, additional, and Zhou, Lin, additional

Published
2022
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26. Structure and Formation Mechanisms in Tantalum and Niobium Oxides in Superconducting Quantum Circuits

Author

Oh, Jin-Su, Zaman, Rahim, Murthy, Akshay A., Bal, Mustafa, Crisa, Francesco, Zhu, Shaojiang, Torres-Castendo, Carlos G., Kopas, Cameron J., Mutus, Joshua Y., Jing, Dapeng, Zasadzinski, John, Grassellino, Anna, Romanenko, Alex, Hersam, Mark C., Bedzyk, Michael J., Kramer, Matt, Zhou, Bi-Cheng, and Zhou, Lin

Abstract

Improving the qubit’s lifetime (T1) is crucial for fault-tolerant quantum computing. Recent advancements have shown that replacing niobium (Nb) with tantalum (Ta) as the base metal significantly increases T1, likely due to a less lossy native surface oxide. However, understanding the formation mechanism and nature of both surface oxides is still limited. Using aberration-corrected transmission electron microscopy and electron energy loss spectroscopy, we found that Ta surface oxide has fewer suboxides than Nb oxide. We observed an abrupt oxidation state transition from Ta2O5to Ta, as opposed to the gradual shift from Nb2O5, NbO2, and NbO to Nb, consistent with thermodynamic modeling. Additionally, amorphous Ta2O5exhibits a closer-to-crystalline bonding nature than Nb2O5, potentially hindering H atomic diffusion toward the oxide/metal interface. Finally, we propose a loss mechanism arising from the transition between two states within the distorted octahedron in an amorphous structure, potentially causing two-level system loss. Our findings offer a deeper understanding of the differences between native amorphous Ta and Nb oxides, providing valuable insights for advancing superconducting qubits through surface oxide engineering.

Published
2024
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