Tunable Ta<sub>x</sub>N Josephson Junctions for Scalable, High Performance, Low Power Computing
ORAL
Abstract
Viable alternatives for high performance, low-power dissipation computing has driven increased interest in superconducting electronics research. Although remarkable progress has been made with Nb/Al-AlOx/Nb Josephson junctions, the necessity for low-temperature processing and the electronic defects associated with AlOX may ultimately limit the ability to scale this technology to the required density. Alternative barriers such as TaN offer a feasible approach to achieve Josephson junctions with suitable IcRn product and thermal stability for existing microfabrication processes.
We present results obtained for Josephson junctions with varying TaXN composition and thicknesses. A clear dependence of junction behavior on stoichiometry and barrier thickness across a wide range of critical currents and IcRn is observed. Conductivity mapping of AlOx and TaN barriers allows a better understanding of the areal distribution of properties across individual junctions.
We present results obtained for Josephson junctions with varying TaXN composition and thicknesses. A clear dependence of junction behavior on stoichiometry and barrier thickness across a wide range of critical currents and IcRn is observed. Conductivity mapping of AlOx and TaN barriers allows a better understanding of the areal distribution of properties across individual junctions.
*This work was supported by IARPA and the LDRD program at Sandia National Laboratories, a multi-mission laboratory managed and operated by NTESS LLC, a wholly owned subsidiary of Honeywell International Inc. for the US DOE NNSA under contract DE-NA0003525.
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Presenters
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Matthaeus Wolak
- Sandia National Laboratories
- Sandia Natl Labs