High Quality Gallium Oxide for Power Electronics. This project aims to combine advanced nanocharacterisation techniques with complementary expertise in semiconductor growth to produce high-quality gallium oxide that will enable fabrication of high efficiency, cost-effective power electronics. These state-of-the-art devices are urgently required to significantly reduce power conversion losses to maximise the performance and benefits of electricity generation systems using renewable energy sources ....High Quality Gallium Oxide for Power Electronics. This project aims to combine advanced nanocharacterisation techniques with complementary expertise in semiconductor growth to produce high-quality gallium oxide that will enable fabrication of high efficiency, cost-effective power electronics. These state-of-the-art devices are urgently required to significantly reduce power conversion losses to maximise the performance and benefits of electricity generation systems using renewable energy sources. The availability of superior oxide materials with bespoke electrical properties will enable the construction of fast high-voltage electronic switches, converters and other components with enhanced performance and unique capabilities.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100036
Funder
Australian Research Council
Funding Amount
$950,000.00
Summary
A customised triple-beam microscope for precise fabricating/characterising . This project aims to establish a customised triple-beam microscope to enable precise fabrication and polishing (using ion beams) and characterisation (using electron beam) of a wide range of advanced materials. It will provide solutions to prepare ultra-high quality and artefact-free specimens for transmission electron microscopy studies, and allow fabrication of unique nanostructures and nanostructured templates for hi ....A customised triple-beam microscope for precise fabricating/characterising . This project aims to establish a customised triple-beam microscope to enable precise fabrication and polishing (using ion beams) and characterisation (using electron beam) of a wide range of advanced materials. It will provide solutions to prepare ultra-high quality and artefact-free specimens for transmission electron microscopy studies, and allow fabrication of unique nanostructures and nanostructured templates for high-performance applications. The customised features of the proposed instrument are the first of its kind in Australia. The new knowledge developed through this project will significantly impact on scientific insights and practical applications of new materials related to physics, chemistry, biology, geology and engineering.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102271
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
High performance organic optoelectronic devices - the role of charge carrier lifetime. Organic solar cells offer a sustainable solution to energy production helping to address the challenge of climate change. This project aims to understand the processes that control device performance and to improve solar cells based upon organic semiconductors with the potential to be extremely cheap, recyclable, and mechanically flexible.
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
Fostering Safe Nanotechnology Research Focused on Critical Public Health Problems. This Project builds upon the applicant's unique interdisciplinary research and collaborations to develop an innovative framework for improving occupational health and safety standards of nanotechnology research at the Australian National University and fostering its focus on critical public health problems such as biosecurity, food and water safety, pollution control and equitable access to health technologies.
Engineering an artificial protein molecular motor. This project aims to use non-motor protein building blocks to construct an artificial protein motor. Nature already uses nanotechnology as the basis for all its machinery, and uses proteins to construct machines. Each protein component in the motor will have a well-understood function; this artificial protein will elucidate how it converts chemical energy to motion. This process is not understood as molecular motors do not obey the same principl ....Engineering an artificial protein molecular motor. This project aims to use non-motor protein building blocks to construct an artificial protein motor. Nature already uses nanotechnology as the basis for all its machinery, and uses proteins to construct machines. Each protein component in the motor will have a well-understood function; this artificial protein will elucidate how it converts chemical energy to motion. This process is not understood as molecular motors do not obey the same principles as macroscopic machines. Comparing the artificial motor with biological motors will provide insight into the workings of natural motors. This project should lead to molecular motors for nanobiotechnology.Read moreRead less
Magnetofection In An Oscillating Magnetic Field. The success of genetic engineering is largely dependent on the ability of transfection agents to deliver genes. Low transfection efficiency is now widely recognised as a critical bottleneck to successful gene delivery. The recent emphasis on the development of nanoscale delivery agents has led to new physics and chemistry-based techniques, which take advantage of charge interactions and energetic processes. This multidisciplinary project aims to a ....Magnetofection In An Oscillating Magnetic Field. The success of genetic engineering is largely dependent on the ability of transfection agents to deliver genes. Low transfection efficiency is now widely recognised as a critical bottleneck to successful gene delivery. The recent emphasis on the development of nanoscale delivery agents has led to new physics and chemistry-based techniques, which take advantage of charge interactions and energetic processes. This multidisciplinary project aims to address this highly significant problem by developing a novel methodology to manipulate nanoparticles under the influence of an oscillating magnetic field to achieve high transfection efficiencies in a highly relevant model of epigenetic reprogramming.Read moreRead less
Establishing Design Principles Of Polymers For Intracellular Delivery . Engineered polymers have played a central role in the field of bionanotechnology by enabling targeted nanoscale cell interactions. Progress in the field of intracellular delivery is currently affected by a major bottleneck due to the absence of effective polymers that is applicable across the range of bimolecular cargoes. In essence depending on the type of cargo: DNA, RNA or protien, the polymer needs programmability. The l ....Establishing Design Principles Of Polymers For Intracellular Delivery . Engineered polymers have played a central role in the field of bionanotechnology by enabling targeted nanoscale cell interactions. Progress in the field of intracellular delivery is currently affected by a major bottleneck due to the absence of effective polymers that is applicable across the range of bimolecular cargoes. In essence depending on the type of cargo: DNA, RNA or protien, the polymer needs programmability. The limited tunability of traditional polymers agents makes them unsuitable for this particular application. The multidisciplinary project addresses this significant problem by engineering novel sequences of defined polymer based nanoscale agents to achieve efficient delivery in cells.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101542
Funder
Australian Research Council
Funding Amount
$450,154.00
Summary
Impact of humoral immunity on nanoparticle–biological interactions. This project aims to improve the biological applications of nanomaterials by understanding their fundamental interactions with proteins and cells in relevant biological environments. This will create new knowledge on how humoral (antibody-mediated) immunity affects nanomaterials using cutting-edge immunoassays, bio–nano characterisation techniques, and bioinformatics. Expected outcomes of the project include an understanding of ....Impact of humoral immunity on nanoparticle–biological interactions. This project aims to improve the biological applications of nanomaterials by understanding their fundamental interactions with proteins and cells in relevant biological environments. This will create new knowledge on how humoral (antibody-mediated) immunity affects nanomaterials using cutting-edge immunoassays, bio–nano characterisation techniques, and bioinformatics. Expected outcomes of the project include an understanding of how specific antibodies modulate the protein coatings on nanomaterials, which will shed light on how immune cells interact with nanomaterials. This will lead to design principles for nanomaterial properties to improve their effectiveness in delivering drugs and gene therapies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101569
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
A novel graphene-based optical sensing platform. Graphene has extraordinary electronic and optical properties as well as large specific surface area which afford great potential for sensor applications. This project will develop an innovative sensing platform to bring graphene related materials and devices a step closer to practical applications, particularly in biochemical sensors.