TY - THES
AU - Lucas Sletten
AB - Control over the quantum state of macroscopic mechanical oscillators promises advances in
the understanding of fundamental physics as well as the development of new quantum technologies.
Surface acoustic waves are an attractive mechanical system in a quantum context as they can
be designed to interact with many popular quantum platforms, including superconducting qubits.
Moreover, surface acoustic waves are already a mature commercial technology widely used in classical
signal processing where the slow speed of sound (km/s) means structures with long delays and
therefore  ne frequency features can be engineered in chip-scale geometries.
In this thesis, I will describe how quantum acoustics with surface acoustic waves coupled
to superconducting qubits can leverage these long delays to build cavities with high densities of
resonant modes and qubit-phonon interactions precisely tailored in the frequency domain to suit
experimental demands. I  first demonstrate resonant interaction between a transmon qubit and a
multi-mode surface acoustic wave resonator where the qubit-resonator coupling strength exceeds
not only the decay rates of the qubit and resonator but also the spacing between resonant modes
of the cavity. As a natural extension of this result, I describe how intentional shaping of the qubit-cavity
coupler in real space leads to a desirable frequency-dependent interaction strength. This
hybrid system can achieve interaction strengths large enough for the single-phonon Stark shift to
exceed the relevant dissipation rates, leading to the resolution of phonon number states in the qubit
spectrum. I will conclude by evaluating the prospects for improved qubit and acoustic performance
that would enable a host of experiments, in particular showing that the dominant acoustic loss
mechanism, phonon diffraction, can be eliminated by implementing focusing acoustic cavities
BT - Department of Physics
CY - Boulder, CO
DA - 2021-07
N2 - Control over the quantum state of macroscopic mechanical oscillators promises advances in
the understanding of fundamental physics as well as the development of new quantum technologies.
Surface acoustic waves are an attractive mechanical system in a quantum context as they can
be designed to interact with many popular quantum platforms, including superconducting qubits.
Moreover, surface acoustic waves are already a mature commercial technology widely used in classical
signal processing where the slow speed of sound (km/s) means structures with long delays and
therefore  ne frequency features can be engineered in chip-scale geometries.
In this thesis, I will describe how quantum acoustics with surface acoustic waves coupled
to superconducting qubits can leverage these long delays to build cavities with high densities of
resonant modes and qubit-phonon interactions precisely tailored in the frequency domain to suit
experimental demands. I  first demonstrate resonant interaction between a transmon qubit and a
multi-mode surface acoustic wave resonator where the qubit-resonator coupling strength exceeds
not only the decay rates of the qubit and resonator but also the spacing between resonant modes
of the cavity. As a natural extension of this result, I describe how intentional shaping of the qubit-cavity
coupler in real space leads to a desirable frequency-dependent interaction strength. This
hybrid system can achieve interaction strengths large enough for the single-phonon Stark shift to
exceed the relevant dissipation rates, leading to the resolution of phonon number states in the qubit
spectrum. I will conclude by evaluating the prospects for improved qubit and acoustic performance
that would enable a host of experiments, in particular showing that the dominant acoustic loss
mechanism, phonon diffraction, can be eliminated by implementing focusing acoustic cavities
PB - University of Colorado Boulder
PP - Boulder, CO
PY - 2021
EP - 164
T2 - Department of Physics
TI - Quantum Acoustics with Multimode Surface Acoustic Wave Cavities
VL - PhD
ER -