The development of inexpensive negatively charged films to increase the efficiency of commercial solar cells. This project aims to reduce the cost of solar electricity by developing inexpensive, negatively charged dielectric films. When deposited on the surfaces of commercial solar cells, these films will significantly increase cell efficiency, thereby producing more power from a given area.
Discovery Early Career Researcher Award - Grant ID: DE180100167
Funder
Australian Research Council
Funding Amount
$349,600.00
Summary
Unravelling the spin transport properties in organic spintronic devices. This project aims to understand and control spin transport properties in organic semiconductors (OSC) and develop novel organic spintronic devices. OSCs have become the centre of attention in the spintronics community as they have very small spin-orbit coupling and hyperfine interactions, which lead to very long spin coherence times and make them ideal for spin transport. However, the basic mechanisms of spin injection, tra ....Unravelling the spin transport properties in organic spintronic devices. This project aims to understand and control spin transport properties in organic semiconductors (OSC) and develop novel organic spintronic devices. OSCs have become the centre of attention in the spintronics community as they have very small spin-orbit coupling and hyperfine interactions, which lead to very long spin coherence times and make them ideal for spin transport. However, the basic mechanisms of spin injection, transport, and manipulation in OSCs are still obscure. The project expects to clarify the spin-dynamics, which will advance our understandings of spin transport in OSCs and could contribute to the development of spin-based molecular electronics for future applications.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101531
Funder
Australian Research Council
Funding Amount
$419,615.00
Summary
Ferroelectricity in two-dimensions. This project aims to develop a new kind of electronic devices to store and process information. It will demonstrate a new category of ferroelectric material. By combining it with other materials like graphene, it will realise fully two-dimensional and completely new conceptual devices that are capable of preserving information in a non-volatile manner and performing non-destructive information readout. The outcomes will significantly enhance the information de ....Ferroelectricity in two-dimensions. This project aims to develop a new kind of electronic devices to store and process information. It will demonstrate a new category of ferroelectric material. By combining it with other materials like graphene, it will realise fully two-dimensional and completely new conceptual devices that are capable of preserving information in a non-volatile manner and performing non-destructive information readout. The outcomes will significantly enhance the information density, stability and readout protocols. Successful demonstration of non-destructive readout provides a key conceptual step forward for the ferroelectric random-access memory to be widely used as a universal computing memory and provides fundamental support for the electronic industry. Read moreRead less
Diamond superconducting nanowire single photon detectors. This project aims to develop a new type of single photon detector suitable for applications in quantum communication, sensing and metrology by exploiting recent breakthroughs in the discovery of superconductivity in boron doped diamond. This project expects to demonstrate a new, scalable architecture for integrated photonic circuits using the special properties of diamond which allow single-photon quantum emitters, passive optical compone ....Diamond superconducting nanowire single photon detectors. This project aims to develop a new type of single photon detector suitable for applications in quantum communication, sensing and metrology by exploiting recent breakthroughs in the discovery of superconductivity in boron doped diamond. This project expects to demonstrate a new, scalable architecture for integrated photonic circuits using the special properties of diamond which allow single-photon quantum emitters, passive optical components, and single-photon detectors to be integrated into one monolithic diamond chip. Expected outcomes include accelerating the uptake of Australian quantum technologies and strengthening international collaborations. Significant benefits include enhanced advanced materials manufacturing capability. The project also provides a pathway to increase linkages with companies which are commercialising quantum technologies.Read moreRead less
Microanalysis of novel carbon thin films. Carbon coatings are technologically important and have many applications in automotive and biomedical industries worldwide. An example automotive application is as a coating for high performance fuel injectors. Carbon coatings have significant unrealised potential for applications in hostile environments such as those encountered in high performance engineering components and in the human body. Electrical devices can be fabricated with these films suitab ....Microanalysis of novel carbon thin films. Carbon coatings are technologically important and have many applications in automotive and biomedical industries worldwide. An example automotive application is as a coating for high performance fuel injectors. Carbon coatings have significant unrealised potential for applications in hostile environments such as those encountered in high performance engineering components and in the human body. Electrical devices can be fabricated with these films suitable for use in compact electrical devices requiring high current density. This project will add to the techniques used for the analysis of carbon coatings being developed in Australia. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100086
Funder
Australian Research Council
Funding Amount
$489,250.00
Summary
A platform for probing nanoscale magnetic states under multiple actuations. The proposed facility offers unique capabilities to investigate the interactions of spin with charge and lattice under external stimuli of light illumination, mechanical stress and voltage bias at various temperatures in a wide range of functional materials. Precise laser magnetometry and video-rate Kerr microscopy are integrated in a single magneto-optic Kerr effect (MOKE) system. This platform also aims to provide opti ....A platform for probing nanoscale magnetic states under multiple actuations. The proposed facility offers unique capabilities to investigate the interactions of spin with charge and lattice under external stimuli of light illumination, mechanical stress and voltage bias at various temperatures in a wide range of functional materials. Precise laser magnetometry and video-rate Kerr microscopy are integrated in a single magneto-optic Kerr effect (MOKE) system. This platform also aims to provide optical magnetic circular dichroism (OMCD) to assess electronic structures of semiconductors and biomedical materials. It will facilitate multidisciplinary research collaborations between academics and industries to advance next-generation spintronics, optoelectronics, energy conversion and storage, and biomedical technologies.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100033
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
Ultrafast time-resolved optical spectroscopy for advanced multifunctional materials. Ultrafast time resolved optical spectroscopy for advanced multifunctional materials: Time resolved spectroscopy is among the hottest emerging fields in condensed matter physics and offers a new perspective into the complex physics of multifunctional materials like multiferroics or unconventional superconductors. At present, the underlying physics of these novel complex materials is not fully understood and new e ....Ultrafast time-resolved optical spectroscopy for advanced multifunctional materials. Ultrafast time resolved optical spectroscopy for advanced multifunctional materials: Time resolved spectroscopy is among the hottest emerging fields in condensed matter physics and offers a new perspective into the complex physics of multifunctional materials like multiferroics or unconventional superconductors. At present, the underlying physics of these novel complex materials is not fully understood and new experimental approaches such as the proposed time-resolved optical spectroscopy are required. The deeper understanding of the involved phenomena would also allow for a systematic search for new, undiscovered multifunctional materials with similar but enhanced properties. This offers a huge potential for future industry in applications such as in novel sensors, information processing, and high efficiency photovoltaics.Read moreRead less
Transition Metal Oxide Interfaces: Novel Emerging Functionalities. The project aims to investigate transition metal oxide heterostructures, which offer tremendous opportunities for fundamental research and future technological applications because they combine quantum size effects with effects of strong electron correlations such as magnetic switching, multiferroic coupling or superconductivity. Recent advances in growth methods such as pulsed laser deposition enable layer-by-layer growth with ....Transition Metal Oxide Interfaces: Novel Emerging Functionalities. The project aims to investigate transition metal oxide heterostructures, which offer tremendous opportunities for fundamental research and future technological applications because they combine quantum size effects with effects of strong electron correlations such as magnetic switching, multiferroic coupling or superconductivity. Recent advances in growth methods such as pulsed laser deposition enable layer-by-layer growth with atomic precision. The aim of this project is to combine complementary experimental methods (ie neutron scattering and optical spectroscopy), in order to gain a detailed insight into the magnetic and electronic properties of the heterostructures. This is designed to yield a deeper understanding of the underlying physics in order to help develop new materials for next-generation information technology.Read moreRead less
Metal Halide Perovskite Spin-Orbit Torque Devices. This project aims to demonstrate a new, highly efficient spin-based electronic device by developing a fundamental understanding into the generation and transport of spin in metal halide perovskite based heterostructures. Using an interdisciplinary approach, this project expects to exploit the beneficial spin properties, low cost and scalable production methods of metal halide perovskites. It is expected that this project will deliver new functio ....Metal Halide Perovskite Spin-Orbit Torque Devices. This project aims to demonstrate a new, highly efficient spin-based electronic device by developing a fundamental understanding into the generation and transport of spin in metal halide perovskite based heterostructures. Using an interdisciplinary approach, this project expects to exploit the beneficial spin properties, low cost and scalable production methods of metal halide perovskites. It is expected that this project will deliver new functionality to these emerging materials to enable their application in highly efficient spintronic devices. These outcomes should provide significant benefits to the Australian advanced manufacturing sector by developing new knowledge, advanced technology and training skilled professionals.Read moreRead less