Fast dynamics and measurements of single-charge devices
Doctoral thesis, 2010

In this thesis we present measurements on several different devices, including the single-Cooper-pair box (SCB), the single-electron box, tunable superconducting resonators and so called transmon qubits. By exploiting the quantum capacitance of the SCB, its state was measured by embedding the box in a radio-frequency resonator. The state dependent change in the quantum capacitance then leads to a measurable shift in the resonator’s frequency. On-chip, lumped-element resonators, optimized for speed, were fabricated together with the SCB, which allowed for very fast measurements of the state. We have performed pulsed measurements, and were able to show that the state of the SCB can be measured in approximately 50 ns. The normal state of the box was also measured. We observed a gate dependent absorption in the single-electron box, centered around its degeneracy points, when it was driven by an radio-frequency signal. The internal dynamics of the system was analyzed by solving a two-level master equation. We model the dissipation in the box by defining an effective resistance, which we name the “Sisyphus resistance”. With the developed model, we were able to very accurately reproduce the measured response over a wide range of RF amplitudes and temperatures. Measurements on a strongly driven SCB are presented. The response of the driven SCB is explained in terms of longitudinal dressed states, defining an effective two-level system. The coherence times of the dressed two-level system are extracted. Relaxation and dephasing in the dressed basis was analyzed. We analyze the possibility of using tunable superconducting resonators for coupling qubits. The resonance frequency is changed by modifying the inductance of a superconducting quantum interference device incorporated into the resonator. The tunability and tuning speed are investigated. We also present measurements on transmon qubits coupled to the tunable cavity. We show Rabi oscillations and observe coherent interaction between two coupled transmon qubits.

resonator

single-electron box

superconducting devices

decoherence

quantum capacitance

Sisyphus resistance

transmon

single-Cooper-pair box

qubit

rf-reflectometry

Kollektorn
Opponent: Prof. Pertti Hakonen, Aalto University, Helsinki, Finland.

Author

Fredrik Persson

Chalmers, Microtechnology and Nanoscience (MC2)

Tuning the field in a microwave resonator faster than the photon lifetime

Applied Physics Letters,;Vol. 92(2008)p. 203501-

Journal article

Exploring circuit quantum electrodynamics using a widely tunable superconducting resonator

Physica Scripta,;Vol. T137(2009)p. Art. no. 014018-

Journal article

Dressed relaxation and dephasing in a strongly driven two-level system

Physical Review B - Condensed Matter and Materials Physics,;Vol. 81(2010)p. Art. no. 024520-

Journal article

Excess Dissipation in a Single-Electron Box: The Sisyphus Resistance

Nano Letters,;Vol. 10(2010)p. 953-957

Journal article

Subject Categories

Condensed Matter Physics

ISBN

978-91-7385-408-5

Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 3089

Technical report MC2 - Department of Microtechnology and Nanoscience, Chalmers University of Technology: 172

Kollektorn

Opponent: Prof. Pertti Hakonen, Aalto University, Helsinki, Finland.

More information

Created

10/6/2017