Data underlying the PhD thesis: Quantum Acoustics with high-overtone bulk resonators and superconducting qubits (dataset)

Data underlying the PhD thesis: Quantum Acoustics with high-overtone bulk resonators and superconducting qubits

doi:10.4121/fe176584-e015-4019-8e5d-a2c0f998932f.v1

Datacite citation style:

Franse, Jasper; Steele, Gary (2023): Data underlying the PhD thesis: Quantum Acoustics with high-overtone bulk resonators and superconducting qubits. Version 1. 4TU.ResearchData. dataset. https://doi.org/10.4121/fe176584-e015-4019-8e5d-a2c0f998932f.v1

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Dataset

choose version: version 2 - 2024-01-25 (latest)

version 1 - 2023-11-06

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cQAD, cQED, HBAR, Highovertone bulk acoustic resonator (HBAR), Quantum acoustic, qubit, superconducting, Transmon

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by Jasper Franse , Gary Steele

We measured a transmon qubit coupled to an High-overtone Bulk Acoustic Resonator (HBAR) which was fabricated in the cleanroom of Kavli Nanolab Delft.

The fabricated chip was cooled down to ~20 mK in a commercially bought cryofree dilution refrigerator (Oxford Instruments Triton 200). All measurements (single and two tone spectroscopy) were performed on a Vector Network Analyzer (VNA, Keysight PNA N5222A, 10MHz-26.5 GHz) which was connected to the sample using microwave RF cables. Using additional signal generators (Rohde & Schwarz, SMB 100A, 100 kHz - 12.75 GHz) we were able to produce more needed continuous wave tone to AC-Stark shift the qubit. A pulse generator (Rigol DG1022) in combination with a microwave switch (Taylor MW switch SBS-A01TS), both connected to the VNA were used to performed gated two tone spectroscopy for time domain measurement.

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