Name: Patrick Strobeen - MIT
Start: 2026-04-22T09:00:00-04:00
End: 2026-04-22T20:15:00-04:00
Location: IAMM

Patrick Strobeen - MIT

Wednesday 22 April 2026 - 09:00

Monday 20 April 2026
Tuesday 21 April 2026
Wednesday 22 April 2026
09:00 Research Meeting - Wonhee Ko (University of Tennessee, Knoxville)
Research Meeting
- Wonhee Ko (University of Tennessee, Knoxville)
09:00 - 10:00
Room: 233 Ride from hotel to IAMM
10:00 Talk Prep
Talk Prep
10:00 - 10:20
10:20 Materials-driven design of superconducting quantum devices - Patrick Strohbeen (MIT)
Materials-driven design of superconducting quantum devices
- Patrick Strohbeen (MIT)
10:20 - 11:20
Room: 310 Superconducting quantum devices have undergone a massive renaissance since the first demonstration of the Cooper pair box in 1999 [1]. Utilizing the same general material structure (Al/AlOx/Al), much of the dramatic improvement over the past few decades is a direct result of better device engineering and design. However, studies and proposals challenging the standard materials paradigm of superconducting devices have become increasingly popular in recent years as a route towards improving the coherence of such devices. One of the more mature efforts has been to introduce alternative superconducting metals for the base metallization layer, namely Ta [2], replacing the more common Al and Nb metals used in modern devices. Yet, the continued reliance on the Al/AlOx/Al Josephson junction (JJ) remains a pain point, largely due to the lossy amorphous AlOx material and sensitivity of Al to aggressive chemical cleaning procedures. Here, I will discuss some of the efforts I have pursued during my postdoctoral studies at New York University (NYU) in developing new materials for superconducting qubits to overcome long-standing issues that plague this technology. To this end, I developed a process of growing superconducting germanium thin films as a path towards epitaxial JJ structures integrated with group IV substrates [3]. A comprehensive structural, chemical, and electronic study of this material demonstrates the emergence of superconductivity in germanium through heavy substitutional doping of Ga metal. This system offers a unique approach towards epitaxial JJs utilizing doped semiconductors that readily interface with their un-doped phase that enables wafer-scale tri-layer qubit fabrication utilizing pristine crystalline materials. I will conclude with a brief discussion on my work at the Massachusetts Institute of Technology further pursuing the development of materials in superconducting quantum computing technology. [1]: Y. Nakamura, Y. A. Pashkin, and J. S. Tsai, Nature, 398, 786-788 (1999). [2]: M. P. Bland and F. Bahrami et al., Nature, 647, 343-348 (2025). [3]: J. A. Steele and P. J. Strohbeen et al., Nat. Nanotechnol., 20, 1757-1763 (2025).
11:30 Research Meeting - Joon Sue Lee (University of Tennessee, Knoxville)
Research Meeting
- Joon Sue Lee (University of Tennessee, Knoxville)
11:30 - 12:00
Room: 254
12:00 Lunch
Lunch
12:00 - 14:00
14:00 Research Meeting - Ruixing Zhang (Department of Physics and Astronomy, University of Tennessee Knoxville)
Research Meeting
- Ruixing Zhang (Department of Physics and Astronomy, University of Tennessee Knoxville)
14:00 - 14:30
Room: 323
14:30 Research Meeting
Research Meeting
14:30 - 15:00
Room: 303
15:00 Research Meeting - Yishu Wang (University of Tennessee Knoxville)
Research Meeting
- Yishu Wang (University of Tennessee Knoxville)
15:00 - 15:30
Room: 312
15:30 Research Meeting - Hanno Weitering
Research Meeting
- Hanno Weitering
15:30 - 16:00
16:00 Research meeting - Wonhee Ko (University of Tennessee, Knoxville)
Research meeting
- Wonhee Ko (University of Tennessee, Knoxville)
16:00 - 16:30
Room: G028 Lab tour
17:30 Dinner
Dinner
17:30 - 19:00