Coupled acoustic resonator systems with novel acoustic properties

The discovery of topological phases is a remarkable development with profound impact in condensed matter physics. Such systems host robust unidirectional edge states immune to backscattering from local defects or disorders and there exist topological invariants characterizing the global properties....

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Main Author: Yang, Yahui
Other Authors: Zhang Baile
Format: Thesis-Doctor of Philosophy
Language:English
Published: Nanyang Technological University 2021
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Online Access:https://hdl.handle.net/10356/146052
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Institution: Nanyang Technological University
Language: English
id sg-ntu-dr.10356-146052
record_format dspace
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Science::Physics::Acoustics
spellingShingle Science::Physics::Acoustics
Yang, Yahui
Coupled acoustic resonator systems with novel acoustic properties
description The discovery of topological phases is a remarkable development with profound impact in condensed matter physics. Such systems host robust unidirectional edge states immune to backscattering from local defects or disorders and there exist topological invariants characterizing the global properties. Inspired by the potential applications based on their unique properties, tremendous explorations to extend the topological concept to acoustic systems have been witnessed in recent years. Analogues of topological phases of matter have been rapidly developed in acoustic systems, which acts as an excellent platform to study the topological phenomena. Among various kinds of acoustic systems to explore novel acoustic properties, coupled acoustic resonator systems have drawn much attention. The acoustic resonator systems are always of large size in space, making the sample fabrications and experimental measurements easier, and they could be analyzed with tight-binding model in theoretical investigations. In this thesis, three projects to investigate novel properties in sound waves based on coupled acoustic resonator systems are discussed. At first, the topological valley Hall edge states for sound waves are demonstrated. In our design, a two-dimensional periodic acoustic resonator system which directly simulates a gapped graphene monolayer is adopted. The inversion symmetry of the lattice is broken by differing the heights of two resonators within a unit cell, leading to the analogue of valley Hall effect. Similar to a gapped graphene, gapless topological valley edge states are shown at a zigzag domain wall separating different domains with opposite valley Chern numbers, while an armchair domain wall hosts no gapless edge states. Next, the observation of acoustic pseudo-Landau levels is demonstrated. Our system consists of the acoustic resonators specifically arranged according to a triaxial strain field, which can effectively generate a uniform magnetic field in the acoustic system. The acoustic transmission spectra for different strain strengths have been measured, which exhibit transmission gaps near the Dirac frequency due to the formation of acoustic Landau levels. The pressure profiles in the resonators are displayed to demonstrate the changes between spreading and localizing, as the frequency is tuned continuously among different discrete spectral components. Thirdly, the experimental realization of acoustic two-dimensional higher-order topological insulators in acoustic resonator systems is introduced. A second-order triangular-shaped topological insulator on kagome lattice is demonstrated. The nontrivial bulk topology for the lattice is characterized by quantized Wannier centers. Through measuring transmission spectra and acoustic pressure distributions, the topological corner states at three corners are observed. Then, the lattice was extended to three-dimensional and a third-order topological insulator on an anisotropic diamond lattice was implemented, leading to topological corner states at two corners of a rhombohedron-like sample. The work in this thesis has theoretically studied and experimentally investigated topological related novel properties in acoustic resonator systems, ranging from the strain field induced magnetic-like effects, to the bulk polarization. Introducing topological concepts to acoustic systems benefits both two fields; as shown in our work, acoustic resonators system acts as a highly tunable platform for exploring the topological phases, which build on larger scales and thus pose only little fabrication challenges in practical compared to photonic and electronic systems. Meanwhile,topological properties also contribute to the robust control of sound waves, which is desirable for practical wave transport applications and may prompt innovative sound device such as sound lasing.
author2 Zhang Baile
author_facet Zhang Baile
Yang, Yahui
format Thesis-Doctor of Philosophy
author Yang, Yahui
author_sort Yang, Yahui
title Coupled acoustic resonator systems with novel acoustic properties
title_short Coupled acoustic resonator systems with novel acoustic properties
title_full Coupled acoustic resonator systems with novel acoustic properties
title_fullStr Coupled acoustic resonator systems with novel acoustic properties
title_full_unstemmed Coupled acoustic resonator systems with novel acoustic properties
title_sort coupled acoustic resonator systems with novel acoustic properties
publisher Nanyang Technological University
publishDate 2021
url https://hdl.handle.net/10356/146052
_version_ 1759857696489603072
spelling sg-ntu-dr.10356-1460522023-02-28T23:57:07Z Coupled acoustic resonator systems with novel acoustic properties Yang, Yahui Zhang Baile School of Physical and Mathematical Sciences blzhang@ntu.edu.sg Science::Physics::Acoustics The discovery of topological phases is a remarkable development with profound impact in condensed matter physics. Such systems host robust unidirectional edge states immune to backscattering from local defects or disorders and there exist topological invariants characterizing the global properties. Inspired by the potential applications based on their unique properties, tremendous explorations to extend the topological concept to acoustic systems have been witnessed in recent years. Analogues of topological phases of matter have been rapidly developed in acoustic systems, which acts as an excellent platform to study the topological phenomena. Among various kinds of acoustic systems to explore novel acoustic properties, coupled acoustic resonator systems have drawn much attention. The acoustic resonator systems are always of large size in space, making the sample fabrications and experimental measurements easier, and they could be analyzed with tight-binding model in theoretical investigations. In this thesis, three projects to investigate novel properties in sound waves based on coupled acoustic resonator systems are discussed. At first, the topological valley Hall edge states for sound waves are demonstrated. In our design, a two-dimensional periodic acoustic resonator system which directly simulates a gapped graphene monolayer is adopted. The inversion symmetry of the lattice is broken by differing the heights of two resonators within a unit cell, leading to the analogue of valley Hall effect. Similar to a gapped graphene, gapless topological valley edge states are shown at a zigzag domain wall separating different domains with opposite valley Chern numbers, while an armchair domain wall hosts no gapless edge states. Next, the observation of acoustic pseudo-Landau levels is demonstrated. Our system consists of the acoustic resonators specifically arranged according to a triaxial strain field, which can effectively generate a uniform magnetic field in the acoustic system. The acoustic transmission spectra for different strain strengths have been measured, which exhibit transmission gaps near the Dirac frequency due to the formation of acoustic Landau levels. The pressure profiles in the resonators are displayed to demonstrate the changes between spreading and localizing, as the frequency is tuned continuously among different discrete spectral components. Thirdly, the experimental realization of acoustic two-dimensional higher-order topological insulators in acoustic resonator systems is introduced. A second-order triangular-shaped topological insulator on kagome lattice is demonstrated. The nontrivial bulk topology for the lattice is characterized by quantized Wannier centers. Through measuring transmission spectra and acoustic pressure distributions, the topological corner states at three corners are observed. Then, the lattice was extended to three-dimensional and a third-order topological insulator on an anisotropic diamond lattice was implemented, leading to topological corner states at two corners of a rhombohedron-like sample. The work in this thesis has theoretically studied and experimentally investigated topological related novel properties in acoustic resonator systems, ranging from the strain field induced magnetic-like effects, to the bulk polarization. Introducing topological concepts to acoustic systems benefits both two fields; as shown in our work, acoustic resonators system acts as a highly tunable platform for exploring the topological phases, which build on larger scales and thus pose only little fabrication challenges in practical compared to photonic and electronic systems. Meanwhile,topological properties also contribute to the robust control of sound waves, which is desirable for practical wave transport applications and may prompt innovative sound device such as sound lasing. Doctor of Philosophy 2021-01-22T02:48:00Z 2021-01-22T02:48:00Z 2020 Thesis-Doctor of Philosophy Yang, Y. (2020). Coupled acoustic resonator systems with novel acoustic properties. Doctoral thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/146052 10.32657/10356/146052 en This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License (CC BY-NC 4.0). application/pdf Nanyang Technological University