Dynamic Mechano-Microscopy for use in Mechanobiology . We will develop an innovative microscope that will enable new discoveries in biology. Most microscopes form images of a sample's optical properties, instead we will image a sample's mechanical properties. The reason our novel approach is needed is that cell behaviour depends on the stiffness of it's environment, but current microscopes are unable to image this. Our microscope will provide insights in biology that can improve our understandi ....Dynamic Mechano-Microscopy for use in Mechanobiology . We will develop an innovative microscope that will enable new discoveries in biology. Most microscopes form images of a sample's optical properties, instead we will image a sample's mechanical properties. The reason our novel approach is needed is that cell behaviour depends on the stiffness of it's environment, but current microscopes are unable to image this. Our microscope will provide insights in biology that can improve our understanding of cells, the building blocks of life. We will achieve this by: 1. Developing a microscope that combines microscopic resolution with rapid imaging; 2: Developing the capability to image both within the cell and its surrounding environment; and 3. Using our microscope to make discoveries in biology.Read moreRead less
Violation of fundamental symmetries in atoms, molecules and nuclei. This theoretical project aims to predict enhanced effects of parity (P), time reversal (T), CP and Lorentz invariance violation, which may be measured using atomic spectroscopy and nuclear physics methods. This project expects to contribute to search for physics beyond standard model, including standard model extensions predicting axion, dark matter and T,P-violating electric dipole moments. Expected outcomes include predictions ....Violation of fundamental symmetries in atoms, molecules and nuclei. This theoretical project aims to predict enhanced effects of parity (P), time reversal (T), CP and Lorentz invariance violation, which may be measured using atomic spectroscopy and nuclear physics methods. This project expects to contribute to search for physics beyond standard model, including standard model extensions predicting axion, dark matter and T,P-violating electric dipole moments. Expected outcomes include predictions of new enhanced effects in nuclei, atoms and molecules. By-products and benefits include development of high precision computer codes for atomic calculations, which are expected to have numerous applications including photon and electron processes, properties of superheavy elements and atomic clocks.Read moreRead less
Probing new physics with atomic parity violation. This project aims to provide a new level of rigour in tests of the standard model of particle physics at low energies, and to reveal or more tightly constrain new particles or forces. This will involve the development of state-of-the-art atomic theory techniques and collaboration with world-leading experimental groups. The expected outcomes and benefits include a breakthrough in the precision of atomic theory calculations, new insights into nucle ....Probing new physics with atomic parity violation. This project aims to provide a new level of rigour in tests of the standard model of particle physics at low energies, and to reveal or more tightly constrain new particles or forces. This will involve the development of state-of-the-art atomic theory techniques and collaboration with world-leading experimental groups. The expected outcomes and benefits include a breakthrough in the precision of atomic theory calculations, new insights into nuclear magnetic structure, improved determination of fundamental particle physics parameters, stronger ties with the international experimental community, enhancing Australian leadership and expertise, and high-level training of the next generation of scientists.Read moreRead less
Harnessing opto-acoustic interactions for on-chip optical isolation. The project aims to develop practical on-chip photonic isolators – one-way optical circuits – by harnessing light–sound interactions in a nanoscale platform novel in its materials, design and mechanism. The project should develop new nanofabrication techniques and transform understanding of the physics of one-way photonic processes. Expected outcomes include enhanced design and fabrication capabilities for photonic circuits, ul ....Harnessing opto-acoustic interactions for on-chip optical isolation. The project aims to develop practical on-chip photonic isolators – one-way optical circuits – by harnessing light–sound interactions in a nanoscale platform novel in its materials, design and mechanism. The project should develop new nanofabrication techniques and transform understanding of the physics of one-way photonic processes. Expected outcomes include enhanced design and fabrication capabilities for photonic circuits, ultra-compact, high-performance optical isolators and circulators that shield sensitive optical components, and a suite of theoretical tools for describing propagation and noise in these devices. These new high performance photonic circuits should benefit telecommunications, radar, defence, and sensing applications. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100625
Funder
Australian Research Council
Funding Amount
$446,700.00
Summary
Integrated slab-mode beam engineering for handheld terahertz systems. Current dominant system architectures for terahertz waves are adapted from other ranges, leading to critical bottlenecks. This project will address this with a new integration platform that is tailored to the particular needs of terahertz waves. This requires advances in the emerging field of micro-scale integrated optics, combined with antenna-theory principles, semiconductor science, and advanced microfabrication to incorpor ....Integrated slab-mode beam engineering for handheld terahertz systems. Current dominant system architectures for terahertz waves are adapted from other ranges, leading to critical bottlenecks. This project will address this with a new integration platform that is tailored to the particular needs of terahertz waves. This requires advances in the emerging field of micro-scale integrated optics, combined with antenna-theory principles, semiconductor science, and advanced microfabrication to incorporate active devices. Novel spatially-dependent dispersion engineering techniques will also be pioneered for phased-array-free beamforming. This will enable a broad variety of all-in-one handheld systems for practical applications of terahertz waves such as noninvasive standoff sensing and self-aligning wireless links.Read moreRead less
Shedding Light on the Proton Radius Puzzle with Ultracold Helium. This project aims to shed light on an outstanding discrepancy in physics known as the proton radius puzzle, first seen in hydrogen but now being studied in helium. Capitalising on existing international collaboration between experiment and theory to exploit the advantages of ultracold helium, this project aims to determine the isotopic nuclear charge radius difference with unprecedented precision, using our state-of-the-art quantu ....Shedding Light on the Proton Radius Puzzle with Ultracold Helium. This project aims to shed light on an outstanding discrepancy in physics known as the proton radius puzzle, first seen in hydrogen but now being studied in helium. Capitalising on existing international collaboration between experiment and theory to exploit the advantages of ultracold helium, this project aims to determine the isotopic nuclear charge radius difference with unprecedented precision, using our state-of-the-art quantum electrodynamic theory. This will not only answer fundamental questions about helium atomic structure, but may also reveal new physics beyond the current Standard Model. The validation of atomic structure theory should provide benefits in applications including the realisation of more accurate atomic clocks.Read moreRead less
Next generation lasers for short-reach optical fibre communication. This project aims to develop next-generation laser systems for multimode fibre-optic communication systems, by leveraging recently developed techniques for measuring and controlling the spatial properties of light. These techniques will provide new insights into the physics of the lasers themselves, as well as overcoming fundamental limitations which have traditionally hindered their operation at high speed. The expected outcome ....Next generation lasers for short-reach optical fibre communication. This project aims to develop next-generation laser systems for multimode fibre-optic communication systems, by leveraging recently developed techniques for measuring and controlling the spatial properties of light. These techniques will provide new insights into the physics of the lasers themselves, as well as overcoming fundamental limitations which have traditionally hindered their operation at high speed. The expected outcome of this project is the inclusion of these techniques in the development and operation of future generations of fibre communication systems. Creating new classes of laser systems, which can scale to large bit rates, will enable the growth in this area to be sustained into the future.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100509
Funder
Australian Research Council
Funding Amount
$436,482.00
Summary
Going Fourth: ruling light with pure-quartic solitons. This project aims to develop a novel integrated high-energy light source through the combination of nanoscience and optics. The core research of this project addresses the energy limitation inherent to the current technology which has hindered its use in real applications. Expected outcomes include new knowledge, with publication in world-class scientific journals, and disruptive technological capabilities in miniaturized photonics. The expe ....Going Fourth: ruling light with pure-quartic solitons. This project aims to develop a novel integrated high-energy light source through the combination of nanoscience and optics. The core research of this project addresses the energy limitation inherent to the current technology which has hindered its use in real applications. Expected outcomes include new knowledge, with publication in world-class scientific journals, and disruptive technological capabilities in miniaturized photonics. The expected benefit is to generate high-energy pulses from a battery powered micro-chip that could enhance spectroscopy sensing devices for real-world applications, outside laboratories. This project will strengthen Australian capabilities and expertise in cutting-edge nanotechnology and photonics.Read moreRead less
Ion-atom collision data for fusion energy, hadron therapy and astrophysics. This project aims to combine experimental and theoretical efforts to generate accurate data required for the development and maintenance of fusion reactors, treatment planning in hadron therapy of cancerous tumours, and modelling astrophysical phenomena. Hadron therapy has been used successfully worldwide for over a decade with Australia’s first such facility, the Bragg Centre for Proton Therapy, currently under construc ....Ion-atom collision data for fusion energy, hadron therapy and astrophysics. This project aims to combine experimental and theoretical efforts to generate accurate data required for the development and maintenance of fusion reactors, treatment planning in hadron therapy of cancerous tumours, and modelling astrophysical phenomena. Hadron therapy has been used successfully worldwide for over a decade with Australia’s first such facility, the Bragg Centre for Proton Therapy, currently under construction. Fusion reactors are a source of abundant green energy. Immense progress is being made in their construction and underlying technology. Currently, there is an urgent demand for accurate data on ion-beam collisions with atoms and molecules for the aforementioned applications. This project intends to meet this demand.Read moreRead less
Electron-molecule collisions in fusion and astrophysical plasmas. This project will apply innovative methods developed in Australia to accurately model electron collisions with diatomic hydrides. It will generate new knowledge of the dynamics underlying fundamental chemical reactions, and bring international scientists together to study the influence of molecules in plasmas more accurately than ever before. Outcomes will include essential diagnostics for fusion reactors, methods for using the Ja ....Electron-molecule collisions in fusion and astrophysical plasmas. This project will apply innovative methods developed in Australia to accurately model electron collisions with diatomic hydrides. It will generate new knowledge of the dynamics underlying fundamental chemical reactions, and bring international scientists together to study the influence of molecules in plasmas more accurately than ever before. Outcomes will include essential diagnostics for fusion reactors, methods for using the James Webb Space Telescope to study astrophysical clouds, and strengthened ties between Australia and the global plasma physics community. The significant benefits will include accelerating the development of fusion technology as an alternative to fossil fuels, and furthering our understanding of stellar evolution.Read moreRead less