Discovery Early Career Researcher Award - Grant ID: DE240100627
Funder
Australian Research Council
Funding Amount
$436,250.00
Summary
Topological phonons in solids. This project aims to create a complete list of possible topological phonons in time-reversal-invariant systems via symmetry analysis, to determine ideal topological phononic materials, and to study topological phonon-related properties and possible applications. The significant outcomes of this project will be the generation of new knowledge that will help conclude the search for novel topological phonons and the prediction of novel topological phononic materials b ....Topological phonons in solids. This project aims to create a complete list of possible topological phonons in time-reversal-invariant systems via symmetry analysis, to determine ideal topological phononic materials, and to study topological phonon-related properties and possible applications. The significant outcomes of this project will be the generation of new knowledge that will help conclude the search for novel topological phonons and the prediction of novel topological phononic materials based on the complete classification list of topological phonons. The outcomes of this project should unlock the physics of the exotic topological phonons and lay a solid foundation for applying topological phononic materials based on their unprecedented properties.Read moreRead less
Topological semiconductors resonate with an elusive form of radiation. The aims of the project are to fill a substantial knowledge gap in a class of novel semiconductors that can function as sensors in a frequency range where conventional semiconductors do not work. The way these materials interact with light is not fully understood. The project expects to provide this understanding of great significance and generate new knowledge in physics and materials science. Expected outcomes include a res ....Topological semiconductors resonate with an elusive form of radiation. The aims of the project are to fill a substantial knowledge gap in a class of novel semiconductors that can function as sensors in a frequency range where conventional semiconductors do not work. The way these materials interact with light is not fully understood. The project expects to provide this understanding of great significance and generate new knowledge in physics and materials science. Expected outcomes include a results database that will guide experiments and enable future sensor design. The project expects to provide substantial benefits by identifying the best materials for use as sensors in this frequency range, which has applications in communications, defence, and in the Science and Research Priorities of Food and Transport.Read moreRead less