New metal-molecule binding motifs for self-assembled monolayers and nanodevices. The goal of this research is to investigate technologically interesting electronic materials using new molecular assemblies. We explore their application in some fundamental components of molecular electronic systems and anticipate that knowledge gained from our investigations will have significant impact on the field of nanotechnology, especially in the area of molecular electronics. Our basic research will contrib ....New metal-molecule binding motifs for self-assembled monolayers and nanodevices. The goal of this research is to investigate technologically interesting electronic materials using new molecular assemblies. We explore their application in some fundamental components of molecular electronic systems and anticipate that knowledge gained from our investigations will have significant impact on the field of nanotechnology, especially in the area of molecular electronics. Our basic research will contribute to Australia's reputation as a source of innovative research and ideas in an area where there is growing international momentum.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453823
Funder
Australian Research Council
Funding Amount
$445,124.00
Summary
Atomic Force Microscopy Facility for Soft Interfaces. This proposal seeks to establish a specialized atomic force microscopy facility capable of performing measurements on nanometre scales at soft interfaces. This will service the needs of and collaboration between leading researchers at the Universities of Newcastle, Melbourne, New South Wales and James Cook University. The facility will allow direct measurements of properties of the interactions between atoms, molecules and surfaces associated ....Atomic Force Microscopy Facility for Soft Interfaces. This proposal seeks to establish a specialized atomic force microscopy facility capable of performing measurements on nanometre scales at soft interfaces. This will service the needs of and collaboration between leading researchers at the Universities of Newcastle, Melbourne, New South Wales and James Cook University. The facility will allow direct measurements of properties of the interactions between atoms, molecules and surfaces associated with soft interfaces which are required for ongoing research in fluid-fluid interfaces, surfactant and polymer adsorbed layers, and biomolecules as well as to develop new processes in emerging fields of nanotechnology, biotechnology, and medical and pharmaceutical production.Read moreRead less
Development of new methods for the synthesis of plasmonically-active precious metal rods and shells. This project directly addresses the National Research Priority on building and transforming Australian industries. It will position an Australian manufacturer as the world-leading supplier of speciality precious metal nanoparticles. The project is designed to add significant value to the precious metals products emanating from Australia. In addition to benefiting an existing manufacturing operati ....Development of new methods for the synthesis of plasmonically-active precious metal rods and shells. This project directly addresses the National Research Priority on building and transforming Australian industries. It will position an Australian manufacturer as the world-leading supplier of speciality precious metal nanoparticles. The project is designed to add significant value to the precious metals products emanating from Australia. In addition to benefiting an existing manufacturing operation, it is also expected to assist Australian researchers to capture a leadership role in commercialising new applications for these materials.Read moreRead less
Special Research Initiatives - Grant ID: SR0354658
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
The Nanoparticle Network. Nanoscale materials are objects with one dimension less than about 20nm in size. Such exotic materials display unique, size-dependent properties (called "quantum size effects"). These materials will form the basis for many of the technological advances of the 21st Century. "The Nanoparticle Network" is a consortium dedicated to the exploration of different nanoscale materials and the origin of quantum size effects. The Network aims to enhance the uptake of all types of ....The Nanoparticle Network. Nanoscale materials are objects with one dimension less than about 20nm in size. Such exotic materials display unique, size-dependent properties (called "quantum size effects"). These materials will form the basis for many of the technological advances of the 21st Century. "The Nanoparticle Network" is a consortium dedicated to the exploration of different nanoscale materials and the origin of quantum size effects. The Network aims to enhance the uptake of all types of nanoparticle based technologies through an integrated network of scientists and engineers in conjunction with industry partners and government research institutions.
Read moreRead less
Nanotribology and Nanorheometry: A Fundamental Study of the Dynamic Interactions of Particles and Surfaces at the Molecular Level. Friction and deformation occur from the mutual motion and interaction of microscopic particles and surfaces. This research aims to develop new theories and measurement techniques for these non-equilibrium phenomena by combining mathematical analysis and numerical computations with dynamic force measurement, surface modification, and surface characterisation on nanom ....Nanotribology and Nanorheometry: A Fundamental Study of the Dynamic Interactions of Particles and Surfaces at the Molecular Level. Friction and deformation occur from the mutual motion and interaction of microscopic particles and surfaces. This research aims to develop new theories and measurement techniques for these non-equilibrium phenomena by combining mathematical analysis and numerical computations with dynamic force measurement, surface modification, and surface characterisation on nanometre and molecular length scales. These insights and data will be critically important in designing low-friction surfaces that save energy and wear, in developing nanoscopic probes for the mechanical and structural properties of soft polymeric and bio-materials, and in making high performance coatings that control adhesion and particle aggregation in technologically advanced applications.Read moreRead less
Nano-scale tuning: a path to functional materials for hydrogen storage. If the nano-stores discovered can be taken from bench to markets, the way energy is produced and used will be revolutionised. New markets based on clean energy technologies will appear. The emergence of miniaturised hydrogen stores would create unforeseen markets. By utilising Australia's abundant resources in lithium (Li), magnesium (Mg) and aluminium (Al) to store hydrogen, the beneficiaries would be the Australian industr ....Nano-scale tuning: a path to functional materials for hydrogen storage. If the nano-stores discovered can be taken from bench to markets, the way energy is produced and used will be revolutionised. New markets based on clean energy technologies will appear. The emergence of miniaturised hydrogen stores would create unforeseen markets. By utilising Australia's abundant resources in lithium (Li), magnesium (Mg) and aluminium (Al) to store hydrogen, the beneficiaries would be the Australian industry and academia interested in the knowledge gained and the application of the unique features of nano-hydride materials. By reducing the emissions of greenhouse gases, society would also benefit from a cleaner environment and better health.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989567
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
State of the Art Surface Characterisation Facility for the Sydney Basin. Many of the grand challenges of our time, including finding alternative sources of energy, maximizing our current supply of natural resources, identifying and treating pollution in general, and in water in particular, and developing therapies and biomaterials that enable the personalisation of therapies to each individual are being solved using developments in the molecular sciences. Pivotal to the success of such research ....State of the Art Surface Characterisation Facility for the Sydney Basin. Many of the grand challenges of our time, including finding alternative sources of energy, maximizing our current supply of natural resources, identifying and treating pollution in general, and in water in particular, and developing therapies and biomaterials that enable the personalisation of therapies to each individual are being solved using developments in the molecular sciences. Pivotal to the success of such research is to understand materials and surfaces at the molecular level. The request is to purchase surface analysis instrumentation which will dramatically enhance the ability of scientists around Australia understand how to develop solutions to these grand challenges.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101101
Funder
Australian Research Council
Funding Amount
$348,741.00
Summary
Single-Molecule Circuitry for Nanoscale Electronic Devices. The aim of this project is to develop novel methods for forming robust single-molecule circuitry. The use of single molecules in electronics represents the next level of miniaturisation of electronic components, which would enable us to meet the expanding demands of modern technologies and to continue the downscaling trend in electronic devices. This project aims to address the requirements needed to translate single-molecule electronic ....Single-Molecule Circuitry for Nanoscale Electronic Devices. The aim of this project is to develop novel methods for forming robust single-molecule circuitry. The use of single molecules in electronics represents the next level of miniaturisation of electronic components, which would enable us to meet the expanding demands of modern technologies and to continue the downscaling trend in electronic devices. This project aims to address the requirements needed to translate single-molecule electronics from its current status as a fundamental tool to real-world applications. Key approaches will be the use of surface chemistry to develop new methods of wiring single molecules and the integration of robust single-molecule junctions with semiconducting electrodes. The expected project outcomes pave the way for single-molecule electronic and analytical devices.Read moreRead less