Discovery Early Career Researcher Award - Grant ID: DE230100324
Funder
Australian Research Council
Funding Amount
$394,318.00
Summary
Cooperative Single Atom Catalysts for Zn-CO2 Batteries. This project aims to develop cooperative single-atom catalysts for efficient and selective electrocatalytic CO2 conversion and Zn-CO2 batteries. Cooperative catalysts at the single atom limit can potentially achieve enhanced electrochemical properties beyond state-of-the-art and will trigger significant theoretical and technological interests in energy conversion and storage fields. It is expected to generate new knowledge in materials scie ....Cooperative Single Atom Catalysts for Zn-CO2 Batteries. This project aims to develop cooperative single-atom catalysts for efficient and selective electrocatalytic CO2 conversion and Zn-CO2 batteries. Cooperative catalysts at the single atom limit can potentially achieve enhanced electrochemical properties beyond state-of-the-art and will trigger significant theoretical and technological interests in energy conversion and storage fields. It is expected to generate new knowledge in materials science and electrochemistry, using interdisciplinary approaches of atom-precise material engineering, in situ characterisation and full-cell optimisation. Significant economic and environmental benefits are expected from developing carbon-neutral CO2 electrolysers with low cost and high energy efficiency.Read moreRead less
On-Chip Detection and Molecular Fingerprinting of Emerging Toxicants. The project aims to address key questions about the development and integration of advanced materials and functional molecules into cutting-edge analytical tools for screening emerging environmental pollutants. This is expected to generate fundamental and applied knowledge in analytical chemistry, using an interdisciplinary approach to engineer materials with precisely tailored properties for ultra-sensitive and selective dete ....On-Chip Detection and Molecular Fingerprinting of Emerging Toxicants. The project aims to address key questions about the development and integration of advanced materials and functional molecules into cutting-edge analytical tools for screening emerging environmental pollutants. This is expected to generate fundamental and applied knowledge in analytical chemistry, using an interdisciplinary approach to engineer materials with precisely tailored properties for ultra-sensitive and selective detection of extremely persistent toxicants in water. Anticipated outcomes are optical materials and functional molecules, integrated into lab-on-a-chip platforms with advanced features for real-life environmental applications – with significant benefits for addressing major environmental and health treats to our society.Read moreRead less
Bioinspired photo–iontronic membranes for smart neuron-mimicking systems. The project aims to address key fundamental questions about the development of bioinspired artificial nanochannels that can precisely mimic current signals and functionalities in neurons. This is expected to generate fundamental and applied knowledge in bioengineered photo–iontronic systems, harnessing a multidisciplinary approach to engineer materials with precisely tailored properties at the nanoscale for unprecedented d ....Bioinspired photo–iontronic membranes for smart neuron-mimicking systems. The project aims to address key fundamental questions about the development of bioinspired artificial nanochannels that can precisely mimic current signals and functionalities in neurons. This is expected to generate fundamental and applied knowledge in bioengineered photo–iontronic systems, harnessing a multidisciplinary approach to engineer materials with precisely tailored properties at the nanoscale for unprecedented dynamic control over ionic current through responsive, adaptable neuron-mimicking nanopores. Anticipated outcomes are advanced materials, integrated into smart architectures to overcome the limitations of solid-state systems for the next generation of integrated circuits, bio-interfacial sensors, and energy generators.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100040
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
Advanced capabilities for surface engineering and nanolithography . Advanced capabilities for surface engineering and nanolithography: This project will establish a facility for atomic layer deposition and nanolithography. Strong fabrication and engineering capabilities are key in keeping interdisciplinary research highly competitive. The applications of these cutting-edge surface nanoengineering technologies are enormous and include: development of new materials with new properties for sensing, ....Advanced capabilities for surface engineering and nanolithography . Advanced capabilities for surface engineering and nanolithography: This project will establish a facility for atomic layer deposition and nanolithography. Strong fabrication and engineering capabilities are key in keeping interdisciplinary research highly competitive. The applications of these cutting-edge surface nanoengineering technologies are enormous and include: development of new materials with new properties for sensing, biosensing, optical, photonic, electronic and medical devices, new metamaterials, solar cell, energy production and environmental protection.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100040
Funder
Australian Research Council
Funding Amount
$1,375,000.00
Summary
An advanced electron microscope facility for nanomaterials, functional materials and minerals. An advanced electron microscope facility for nanomaterials, functional materials and minerals: Recent advances in electron microscopy provide instruments that can resolve at the atomic level and image both morphologically and chemically at these resolutions. These modern instruments are also less complex to operate therefore allowing many more researchers to access them directly. The High Resolution Sc ....An advanced electron microscope facility for nanomaterials, functional materials and minerals. An advanced electron microscope facility for nanomaterials, functional materials and minerals: Recent advances in electron microscopy provide instruments that can resolve at the atomic level and image both morphologically and chemically at these resolutions. These modern instruments are also less complex to operate therefore allowing many more researchers to access them directly. The High Resolution Scanning Transmission Electron Microscope will allow a complete, nano-scale characterisation of natural and synthetic materials in a broad range of scientific, engineering and industrial applications. The Field Emission Scanning Electron Microscope will provide nano-science users with a tool that can image many of the processes in the formation of these nanostructures and particles.Read moreRead less
Carbon nanotube based chromatography. This project will reveal new insights into fundamental phenomena of molecular separation processes by carbon nanotubes and underpinning the development of a new generation of microchip separation devices that have the potential to revolutionise chromatographic techniques currently applied in genomics, proteomics, forensics and biotechnology.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100129
Funder
Australian Research Council
Funding Amount
$530,721.00
Summary
State-of-the-art atomic force microscopy facilities for South Australia. This project aims to transform our national capability in nano-(bio)characterisation by establishing a state-of-the-art atomic force microscopy (AFM) facility in South Australia. The facility will provide unparalleled capabilities not currently available in Australia and will catapult knowledge in multiple fields, from critical minerals and clean energy to mechanobiology. Expected outcomes include more efficient and eco-fri ....State-of-the-art atomic force microscopy facilities for South Australia. This project aims to transform our national capability in nano-(bio)characterisation by establishing a state-of-the-art atomic force microscopy (AFM) facility in South Australia. The facility will provide unparalleled capabilities not currently available in Australia and will catapult knowledge in multiple fields, from critical minerals and clean energy to mechanobiology. Expected outcomes include more efficient and eco-friendly resource recovery and energy production, future foods and cures, and advanced (bio)materials. The project will strengthen and amplify Australia’s capacity and global leadership to translate fundamental nano-scale phenomena and properties into innovative materials, technologies, and processes.Read moreRead less
Organically-Capped Copper Nanowires for Soft Electronic Skin Sensors. Soft skin-like electronics can enable applications that are impossible to achieve with today's rigid circuit board technologies. However, it is difficult to realise such future soft electronics with traditional materials and conventional manufacturing methodologies. This project aims to synthesise novel organically-capped copper nanowires as electronic inks (e-inks) for developing cost-effective, soft, stretchable conductor (e ....Organically-Capped Copper Nanowires for Soft Electronic Skin Sensors. Soft skin-like electronics can enable applications that are impossible to achieve with today's rigid circuit board technologies. However, it is difficult to realise such future soft electronics with traditional materials and conventional manufacturing methodologies. This project aims to synthesise novel organically-capped copper nanowires as electronic inks (e-inks) for developing cost-effective, soft, stretchable conductor (e-skin) sensors, which are wearable for monitoring blood pulses, body motions and hand gestures in real-time and in situ. This is expected to advance our knowledge in nanotechnology and generate patentable technologies in soft e-skin sensors, and to bring significant scientific and economic gains to Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101788
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Shape sorting of nanoparticles at oil-water interfaces in microchannels. This project aims to study the effect of shape on the adsorption of nanoparticles at an oil/water interface and develop a rapid, inexpensive, efficient, versatile method for shape sorting of nanoparticles using a microfluidic approach. This technique can be applied for fractionation of synthetic nanoparticles, biosample analysis and environmental monitoring.
ARC Centre of Excellence for Nanoscale BioPhotonics. The CNBP brings together physicists, chemists and biologists focused on a grand challenge controlling nanoscale interactions between light and matter to probe the complex and dynamic nanoenvironments within living organisms. The emerging convergence of nanoscience and photonics offers the opportunity of using light to interrogate nanoscale domains, providing unprecedentedly localised measurements. This will allow biological scientists to unde ....ARC Centre of Excellence for Nanoscale BioPhotonics. The CNBP brings together physicists, chemists and biologists focused on a grand challenge controlling nanoscale interactions between light and matter to probe the complex and dynamic nanoenvironments within living organisms. The emerging convergence of nanoscience and photonics offers the opportunity of using light to interrogate nanoscale domains, providing unprecedentedly localised measurements. This will allow biological scientists to understand how single cells react to and communicate with their surroundings. This science will underpin a new generation of devices capable of probing the response of cells within individuals to environmental conditions or treatment, creating innovative and powerful new sensing platforms.Read moreRead less