Nano-Rheology and Nano-Tribology: Atomistic Simulation of Boundary Lubrication. Manufacturing in atomic level is going to transform the efficiency level in many important applications. As molecular biology transformed medical and biological sciences,so molecular level material design and the techniques involved are going to significantly affect the engineering applications and manufacturing in coming decades. We have no doubt the benefits will flow from the project to many disciplines that are c ....Nano-Rheology and Nano-Tribology: Atomistic Simulation of Boundary Lubrication. Manufacturing in atomic level is going to transform the efficiency level in many important applications. As molecular biology transformed medical and biological sciences,so molecular level material design and the techniques involved are going to significantly affect the engineering applications and manufacturing in coming decades. We have no doubt the benefits will flow from the project to many disciplines that are critical in manufacturing and commercialisation of nano-devices. The results will position Australia in the forefront of one of the most important leading edge technologies in the world. This not only will improve Australia's research profile in the world but also will enable it to capitalize on any future commercial outcomesRead moreRead less
The mechanical and electrical behaviour of boron nitride nanotubes: Insight from in-situ transmission electron microscopy investigation. Boron nitride nanotubes are an emerging class of inorganic nanotubes with insulating property, exceptional thermal stability, high thermal conductivity, and superior mechanical properties including ultrahigh strength and elastic modulus which are not possible in conventional materials. This project aims to apply state-of-the-art in-situ transmission electron mi ....The mechanical and electrical behaviour of boron nitride nanotubes: Insight from in-situ transmission electron microscopy investigation. Boron nitride nanotubes are an emerging class of inorganic nanotubes with insulating property, exceptional thermal stability, high thermal conductivity, and superior mechanical properties including ultrahigh strength and elastic modulus which are not possible in conventional materials. This project aims to apply state-of-the-art in-situ transmission electron microscopy techniques to explore the dependence of mechanical properties on size, morphology and structure of boron nitride nanotubes and the effect of mechanical strain on electrical properties, which will provide opportunities for composite materials reinforcement via nanotubes, and tune the electronic and optoelectronic properties of nanotubes via strain engineering.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100067
Funder
Australian Research Council
Funding Amount
$390,000.00
Summary
The Vevo 2100 Micro-ultrasound plus LAZR Photoacoustic Imaging Platform . The Vevo 2100 micro-ultrasound plus LAZR photoacoustic imaging platform: The Vevo/LAZR ultrasound/photoacoustic imaging facility will allow researchers to achieve multiple outcomes: to visualise and quantify, non-invasively, tissue and molecular structures; the movement and behaviour of cells; and the delivery patterns of administered imaging dyes and nanoparticles in mouse models and reconstructed tissues. This will enabl ....The Vevo 2100 Micro-ultrasound plus LAZR Photoacoustic Imaging Platform . The Vevo 2100 micro-ultrasound plus LAZR photoacoustic imaging platform: The Vevo/LAZR ultrasound/photoacoustic imaging facility will allow researchers to achieve multiple outcomes: to visualise and quantify, non-invasively, tissue and molecular structures; the movement and behaviour of cells; and the delivery patterns of administered imaging dyes and nanoparticles in mouse models and reconstructed tissues. This will enable researchers to obtain anatomical, functional, physiological and molecular data simultaneously and in real-time, with resolution down to 40 micrometres. This will translate into both user efficiency and laboratory cost effectiveness, but more significantly is expected to result in greater understanding of fundamental mechanisms regulating the body's cell and tissue functions.Read moreRead less
Multi-scale Modelling and Simulation of Self-assembling Photonic Crystals. By using bandgaps and introduced defect states, photonic crystals provide the opportunities to shape and mould the flow of light. A success in fabricating 3D photonic crystals with complete bandgaps in a controllable and large-scale fashion will revolutionise the information & telecommunication industry. This ability will provide Australia with a significant niche opportunity at the leading edge of this frontier technolog ....Multi-scale Modelling and Simulation of Self-assembling Photonic Crystals. By using bandgaps and introduced defect states, photonic crystals provide the opportunities to shape and mould the flow of light. A success in fabricating 3D photonic crystals with complete bandgaps in a controllable and large-scale fashion will revolutionise the information & telecommunication industry. This ability will provide Australia with a significant niche opportunity at the leading edge of this frontier technology. It builds on Australia's established strength in material science, photonics, and information & communication technology. The mathematical models, simulation platform, and fabrication methods developed in this project will also be applicable to creating other highly-structured, functional materials.Read moreRead less
Novel 2-photon atom manipulation for ultra-nanoscale processing of diamond. There is intense interest in exploiting diamond's remarkable properties in many fields of science and technology, but fabricating and processing devices remains a major challenge. This project will build on previous work, using a recently discovered novel laser-induced surface phenomenon that enables, for the first time for any material, the exciting prospect of using light to manipulate surface atoms with atomic precis ....Novel 2-photon atom manipulation for ultra-nanoscale processing of diamond. There is intense interest in exploiting diamond's remarkable properties in many fields of science and technology, but fabricating and processing devices remains a major challenge. This project will build on previous work, using a recently discovered novel laser-induced surface phenomenon that enables, for the first time for any material, the exciting prospect of using light to manipulate surface atoms with atomic precision. This project aims to elucidate the mechanisms underpinning the optical interaction to reveal its full potential and use it to address key problems in diamond nano-device fabrication that lie beyond the reach of current techniques. It is expected that the outcomes will directly enhance Australia's current strengths in diamond-based quantum and photonic technologies.Read moreRead less
Rational Design of Novel Multiferroic Materials for Energy Harvesting and Energy Efficiency. Multiferroics are a class of fundamentally complex materials in which several ferroic orders (for example, ferroelectric and ferromagnetic) coexist. The coupling between their electric and magnetic degrees of freedom is controllable via stress and external fields, thus opening the possibility for breakthrough technological developments. By working at the frontier of complex nanostructured oxide materials ....Rational Design of Novel Multiferroic Materials for Energy Harvesting and Energy Efficiency. Multiferroics are a class of fundamentally complex materials in which several ferroic orders (for example, ferroelectric and ferromagnetic) coexist. The coupling between their electric and magnetic degrees of freedom is controllable via stress and external fields, thus opening the possibility for breakthrough technological developments. By working at the frontier of complex nanostructured oxide materials, this project aims to establish the rational basis for systematic design of novel artificially layered multiferroics, develop accurate and computationally affordable methods to simulate these materials under finite-temperature conditions, and exploit this knowledge to devise likely revolutionary photovoltaic, nanoelectronic and energy conversion applications.Read moreRead less
Directed assembly and photoelectric properties of core-shell nanowire networks of PbSe-TiO2 heterostructures for high efficiency low-cost solar cells. The proposed program is aimed at studying numerous fundamental properties and phenomena of photoelectrochemical cells that have an important impact on environmentally friendly solutions to energy problems. Specifically, solar cells have a significant role in energy markets and in lessening CO2 emissions and other environmental impacts. Solar cell ....Directed assembly and photoelectric properties of core-shell nanowire networks of PbSe-TiO2 heterostructures for high efficiency low-cost solar cells. The proposed program is aimed at studying numerous fundamental properties and phenomena of photoelectrochemical cells that have an important impact on environmentally friendly solutions to energy problems. Specifically, solar cells have a significant role in energy markets and in lessening CO2 emissions and other environmental impacts. Solar cell technology, coupled with renewable energy sources, has the potential to provide a long-term solution to the energy crisis and the global warming threat. In addition, the strong team to be assembled will reach a leading position in this area of cutting edge technology. The outcomes will benefit Australian industries.Read moreRead less
In Silico Discovery and Design of 2D Ferromagnets for Nanoscale Electronics. Two dimensional (2D) ferromagnets have great promise for next generation electronics, but suffer from small magnetic anistropy and low Curie temperature for application at the ambient condition. This project aims not only to tackle this challenge by discovering and designing 2D ferromagnet with large anistropy and Curie temperature, but also to engineer 2D ferromagnet with highly mobile electron or extra ferroelectricit ....In Silico Discovery and Design of 2D Ferromagnets for Nanoscale Electronics. Two dimensional (2D) ferromagnets have great promise for next generation electronics, but suffer from small magnetic anistropy and low Curie temperature for application at the ambient condition. This project aims not only to tackle this challenge by discovering and designing 2D ferromagnet with large anistropy and Curie temperature, but also to engineer 2D ferromagnet with highly mobile electron or extra ferroelectricity for novel nanoelectronic device. The technological outcomes will impact on the Australian economy through the potential for new knowledge-based electronics industry. Strong collaboration with leading expert will enable this Australian theoretical team to continue to establish itself as a leader in the field of 2D materials.Read moreRead less
A nanoengineered solution to drug delivery in bone. This project presents an exciting new approach of applying nanotechnology to bone research. By combining our expertise in nanoengineering of new materials, mathematical modelling and bone biology, this project will result in a well-characterised model for drug delivery into bone and lead to a new therapeutic approach for treating bone diseases.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100075
Funder
Australian Research Council
Funding Amount
$580,000.00
Summary
Next Generation Small Angle X-Ray Scattering Facility. Next generation small angle X-ray scattering facility: The ability to determine the nanostructure of bulk materials is of utmost importance in an array of cutting-edge research fields. A state-of-the-art small angle X-ray scattering (SAXS) facility will address this for a wide range of materials covering a diverse range of research topics such as energy storage materials, catalytic species, drug delivery systems, protein structures, biologic ....Next Generation Small Angle X-Ray Scattering Facility. Next generation small angle X-ray scattering facility: The ability to determine the nanostructure of bulk materials is of utmost importance in an array of cutting-edge research fields. A state-of-the-art small angle X-ray scattering (SAXS) facility will address this for a wide range of materials covering a diverse range of research topics such as energy storage materials, catalytic species, drug delivery systems, protein structures, biological membranes, medical diagnostics and therapy, magnetic nanosystems, polymers, novel technologies for the clean utilisation of biomass, and minerals processing. The facility will underpin a range of current and planned multidisciplinary research programs leading to vital nanostructural information and innovative research solutions.Read moreRead less