Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100121
Funder
Australian Research Council
Funding Amount
$1,000,000.00
Summary
An analytical transmission electron microscope for the investigation of functional materials, earth processes and novel condensed matter. Sustainablity depends on the delivery of clean energy, pristine water and air, and the manufacture of consumer products with small environmental footprints. Modelling long-term impacts requires an understanding of the hydro-geological cycles. The technologies are well known—efficient electronics, fuel cells, lightweight composites, and so on—but delivery is ....An analytical transmission electron microscope for the investigation of functional materials, earth processes and novel condensed matter. Sustainablity depends on the delivery of clean energy, pristine water and air, and the manufacture of consumer products with small environmental footprints. Modelling long-term impacts requires an understanding of the hydro-geological cycles. The technologies are well known—efficient electronics, fuel cells, lightweight composites, and so on—but delivery is not straightforward. It is clear, however, that novel materials manipulated at fine scales will be key. Transmission electron microscopy (TEM) guides the development of sustainable technologies. The new TEM facility at ANU will accelerate current studies, by enhancing the materials research portfolio, and extending national and international collaborations in materials, geological and earth sciences.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100906
Funder
Australian Research Council
Funding Amount
$367,150.00
Summary
Nanoengineering of low-CO2 geopolymer cements. With increasing pressure for Australia to use environmentally-conscious building materials, geopolymer concrete is an important emerging alternative to traditional concretes. This project will enhance use of this new material by discovering how to control performance and durability through nanoscale experiments and atom-based simulations.
Discovery Early Career Researcher Award - Grant ID: DE160100796
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Superior Adsorption Capability of Nanosheets for Surface Enhanced Raman. This project aims to create nanotechnologies to sense traces of chemical and biological molecules. Surface adsorption is vital to many scientific and industrial fields, but the intrinsic adsorption property of two-dimensional nanomaterials is largely unknown. This project aims to examine the adsorption capability of nanosheets, such as boron nitride, and understand the thickness effect on their adsorption at the molecular s ....Superior Adsorption Capability of Nanosheets for Surface Enhanced Raman. This project aims to create nanotechnologies to sense traces of chemical and biological molecules. Surface adsorption is vital to many scientific and industrial fields, but the intrinsic adsorption property of two-dimensional nanomaterials is largely unknown. This project aims to examine the adsorption capability of nanosheets, such as boron nitride, and understand the thickness effect on their adsorption at the molecular scale. It also aims to demonstrate the use of these nanosheets as substrates in surface-enhanced Raman spectroscopy. Their adsorption capability and other unique properties could improve the sensitivity, efficiency and affordability of this technique in chemical and biological sensing for applications such as air, water and food safety; and pharmaceutical and cosmetic industries.Read moreRead less
Nanometrology of laser-trapped airborne particles. This project aims to develop a new concept of touch-free measuring of physical characteristics of nanoparticles using specially designed optical vortex beams. The new concept will be of direct importance in developing new nanotechnologies demanding ever-increasing purity of every element in the industrial environment and production processes.
Exploiting the self-assembly of hydrophobin proteins to engineer functional nanostructuring surfaces. There is an increasing world-wide demand for advanced nano-biomaterials with novel properties. We will use natural hydrophobin proteins to coat nanodevices and make them more compatible with biological systems. Hydrophobin coatings will be applicable to biosensors, medical devices, diagnostics and drug delivery systems. The research will lead to an understanding of the basic mechanisms of protei ....Exploiting the self-assembly of hydrophobin proteins to engineer functional nanostructuring surfaces. There is an increasing world-wide demand for advanced nano-biomaterials with novel properties. We will use natural hydrophobin proteins to coat nanodevices and make them more compatible with biological systems. Hydrophobin coatings will be applicable to biosensors, medical devices, diagnostics and drug delivery systems. The research will lead to an understanding of the basic mechanisms of protein self-assembly and will have application outcomes that contribute to Australia being an important player in the field of nanotechnology. This is critical for Australia's long term competitiveness and productivity in and beyond the 21st century.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100736
Funder
Australian Research Council
Funding Amount
$362,446.00
Summary
High performing multifunctional silicon nanomaterials for bio-applications. This project aims to develop high-performance, multifunctional silicon nanomaterials, and to understand their physicochemical properties for bio-imaging. A range of high-quality multifunctional silicon-based bio-probes with novel fluorescent and magnetic properties will be developed for enhancing bio-imaging. The outcomes of the project will further strengthen Australia’s leading position in the targeted areas of Advance ....High performing multifunctional silicon nanomaterials for bio-applications. This project aims to develop high-performance, multifunctional silicon nanomaterials, and to understand their physicochemical properties for bio-imaging. A range of high-quality multifunctional silicon-based bio-probes with novel fluorescent and magnetic properties will be developed for enhancing bio-imaging. The outcomes of the project will further strengthen Australia’s leading position in the targeted areas of Advanced Materials and Nanotechnology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100148
Funder
Australian Research Council
Funding Amount
$150,916.00
Summary
An STM/AFM Facility for Electroactive Materials Characterisation. A Scanning Tunnelling Microscope (STM)/Atomic Force Microscope (AFM) facility for electroactive materials characterisation: This project is expected to address an identified need for the characterisation of electroactive structures using scanning probe microscopy and builds on local expertise in allied methods. The instrumentation includes an electrochemical STM for electrical testing of molecular wires, switches, transistors and ....An STM/AFM Facility for Electroactive Materials Characterisation. A Scanning Tunnelling Microscope (STM)/Atomic Force Microscope (AFM) facility for electroactive materials characterisation: This project is expected to address an identified need for the characterisation of electroactive structures using scanning probe microscopy and builds on local expertise in allied methods. The instrumentation includes an electrochemical STM for electrical testing of molecular wires, switches, transistors and other single molecule electronic components, together with a pico-force tunnelling AFM (PF-TUNA) for the measurement and correlation of nano mechanical and electrical properties of fragile structures over larger areas. The facility will be a core asset for researchers that use electroactive material on conducting substrates in fields including fundamental corrosion science, nanotechnology, and moltronics.Read moreRead less
Heat conduction characterisation of buried insulation layers in silicon-on-insulator systems. This project aims to establish a new technique for the accurate characterisation of thermal conduction in buried insulation layers in advanced silicon-on-insulator (SOI) systems. The success of the project will enable the Australian semiconductor industry to develop high performance SOI systems.
Tunable antifouling behaviour on rough surfaces. The impact of subtle variations in nano and micro scale surface roughness on larger scale wetting and antifouling behaviour of surfaces is investigated. This will lead to next generation non-toxic coatings for both medical and marine applications. The environmental implications will be a significant feature of the ongoing assessment of this study.