Nanowire Superinductors
Licentiate thesis, 2018
In this thesis, we demonstrate that a disordered superconductor with a high kinetic inductance can realize a low microwave loss, non-dissipative circuit element with an impedance greater than the quantum resistance (Rq = h/4e^2 = 6.5kΩ). This element, known as a superinductor, can produce a quantum circuit where charge fluctuations are suppressed.
We have fabricated and characterized 20nm thick niobium-nitride nanowires with a width of 40nm, implementing a superinductance with impedance Z = 6.795kΩ. We demonstrate internal quality factors Qi = 2.5×10^4 at single photon excitation, which is significantly higher than values reported in devices with similar materials and geometries. Moreover, we show that the dominant dissipation in our nanowires is not an intrinsic property of the disordered films, but can instead be fully understood within the well-studied framework of two-level systems.
We have fabricated and characterized 20nm thick niobium-nitride nanowires with a width of 40nm, implementing a superinductance with impedance Z = 6.795kΩ. We demonstrate internal quality factors Qi = 2.5×10^4 at single photon excitation, which is significantly higher than values reported in devices with similar materials and geometries. Moreover, we show that the dominant dissipation in our nanowires is not an intrinsic property of the disordered films, but can instead be fully understood within the well-studied framework of two-level systems.
Disordered Superconductors
Superinductance
Superinductor
Resonator
Nanowire
TLS
Author
David Niepce
Chalmers, Microtechnology and Nanoscience (MC2), Quantum Device Physics
Superinductance for very long-lived quantum coherence
Chalmers, 2013-10-01 -- 2014-06-30.
Areas of Advance
Nanoscience and Nanotechnology (SO 2010-2017, EI 2018-)
Subject Categories
Other Physics Topics
Other Electrical Engineering, Electronic Engineering, Information Engineering
Condensed Matter Physics
Infrastructure
Nanofabrication Laboratory
Technical report MC2 - Department of Microtechnology and Nanoscience, Chalmers University of Technology: MC2-392
Publisher
Chalmers