Dynamic Microcages for Cells: Advanced Tools to Interrogate Cell Mechanics. This project aims to develop a suite of movable micro/nanostructures with integrated mechanical and biological sensors, which will be interfaced with cells to investigate how those cells respond to their surrounding physical environment. Expected outcomes are new technologies in micro/nanofabrication, sensing, and advanced imaging, and deep understanding of the biological processes that control tissue formation and repai ....Dynamic Microcages for Cells: Advanced Tools to Interrogate Cell Mechanics. This project aims to develop a suite of movable micro/nanostructures with integrated mechanical and biological sensors, which will be interfaced with cells to investigate how those cells respond to their surrounding physical environment. Expected outcomes are new technologies in micro/nanofabrication, sensing, and advanced imaging, and deep understanding of the biological processes that control tissue formation and repair. These outcomes would impact how 3D microsystems are developed and applied, informing the design of advanced in-vitro cell culture systems. Significant benefits are expected in 3D nano-microengineering, and in generating new knowledge underpinning future advances in stem cell and tissue engineering technologies.Read moreRead less
Photonic crystals at visible wavelengths. Three dimensional sculptured nano-structures made at a very high spatial resolution will open way to control light emission, propagation, and transmission at the visible wavelengths. Optically thin and transparent solar cells will be able to harvest light using structures.
Micro/nano smart surfaces to unlock the potential of multipotent stem cells. This project aims to determine the interplay of micro/nanostructures on stem cell mechanotransduction and to control the cellular environment. It is expected that this will expand our knowledge on how to control stem cell fate. Expected outcomes are novel scalable technologies for micro/nanostructures and smart surfaces, controlled stem-cell expansion and differentiation, and the creation of a library of protein express ....Micro/nano smart surfaces to unlock the potential of multipotent stem cells. This project aims to determine the interplay of micro/nanostructures on stem cell mechanotransduction and to control the cellular environment. It is expected that this will expand our knowledge on how to control stem cell fate. Expected outcomes are novel scalable technologies for micro/nanostructures and smart surfaces, controlled stem-cell expansion and differentiation, and the creation of a library of protein expression based on the cell interactions. These outcomes will provide critical information required for the future development of instructive biomaterials to drive stem cell expansion and tissue-regeneration. Those materials should benefit the future development of efficient and cost-effective regenerative medicine solutions.Read moreRead less
Nano-optics and ultra-thin materials for an infrared spectrometer-on-a-chip. Aims: This project aims to advance optical nanoresonators and ultra-thin materials in the infrared spectral region. The project aims to use this knowledge to demonstrate an infrared spectrometer on a chip.
Significance: Infrared spectroscopy is a powerful method for identifying and study matter but is carried out using instruments that are generally large, heavy, power hungry and costly.
Expected outcomes: It is expec ....Nano-optics and ultra-thin materials for an infrared spectrometer-on-a-chip. Aims: This project aims to advance optical nanoresonators and ultra-thin materials in the infrared spectral region. The project aims to use this knowledge to demonstrate an infrared spectrometer on a chip.
Significance: Infrared spectroscopy is a powerful method for identifying and study matter but is carried out using instruments that are generally large, heavy, power hungry and costly.
Expected outcomes: It is expected that this project will generate knowledge that will allow dramatic reductions in the size, weight, power consumption and cost of infrared spectrometers.
Benefits: This should allow infrared spectrometers to be used in applications for which the size/weight/power consumption/cost of current approaches prevent their use.
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Highly ordered and tuneable mesostructured perfluorosulfonic acid polymers as novel proton exchange membranes for fuel cells. The purpose of the project is to develop an innovative perfluorofonic acid based proton exchange membranes (PEM) with ordered and tuneable mesopores and it is expected that PEM fuel cell power systems based on such new PEMs will have significant impact on the advancement of fuel cell technologies and the reduction in greenhouse gas emission.
Discovery Early Career Researcher Award - Grant ID: DE220100154
Funder
Australian Research Council
Funding Amount
$426,000.00
Summary
Engineering twisted two-dimensional materials for mid-infrared detectors. This project aims to engineer twisted two-dimensional materials and develop efficient room-temperature mid-infrared detectors that sense both the intensity and polarisation of light. This project expects to generate a cost-effective, ultra-compact, and multifunctional mid-infrared optical platform with high energy conversion efficiency towards advanced sensing and imaging systems. The anticipated goal of this project is to ....Engineering twisted two-dimensional materials for mid-infrared detectors. This project aims to engineer twisted two-dimensional materials and develop efficient room-temperature mid-infrared detectors that sense both the intensity and polarisation of light. This project expects to generate a cost-effective, ultra-compact, and multifunctional mid-infrared optical platform with high energy conversion efficiency towards advanced sensing and imaging systems. The anticipated goal of this project is to deliver high value-added devices with reduced energy consumption for the electronics and photonics industries. This should provide significant economic and environmental benefits by realising technological innovations, savings in materials and energy costs, and reduced environmental impact in advanced manufacturing.Read moreRead less
Nitride materials: In the “bond ionicity Goldilocks zone” for solar energy. Progress towards commercial devices for solar-driven hydrogen generation as well as in-situ electricity generation for vehicles is currently hampered by a lack of earth-abundant, stable, non-toxic semiconductor materials that can be fabricated by scalable methods. This project aims to develop the first scalable solution synthesis methods for a new class of earth-abundant Zn-based nitride semiconductor nanocrystals that h ....Nitride materials: In the “bond ionicity Goldilocks zone” for solar energy. Progress towards commercial devices for solar-driven hydrogen generation as well as in-situ electricity generation for vehicles is currently hampered by a lack of earth-abundant, stable, non-toxic semiconductor materials that can be fabricated by scalable methods. This project aims to develop the first scalable solution synthesis methods for a new class of earth-abundant Zn-based nitride semiconductor nanocrystals that have favourable bond ionicity and establish their optoelectronic properties for renewable energy devices for the first time. Flexible solution processing methods will be exploited to tune surface composition, remove defects and create devices to achieve optimised performance in these challenging new nitride material systems.Read moreRead less
Understanding dynamic interfaces in electrochemical systems. This project aims to develop nanoscale characterisation methods to understand dynamic processes in zinc-ion batteries and high temperature electrolysis systems under real working (in operando) conditions. This project expects to reveal critical solid-liquid and solid-gas interfacial processes in these two distinctly different electrochemical systems. The expected outcomes include improved understanding of electrochemical interfaces and ....Understanding dynamic interfaces in electrochemical systems. This project aims to develop nanoscale characterisation methods to understand dynamic processes in zinc-ion batteries and high temperature electrolysis systems under real working (in operando) conditions. This project expects to reveal critical solid-liquid and solid-gas interfacial processes in these two distinctly different electrochemical systems. The expected outcomes include improved understanding of electrochemical interfaces and improved tools and methods to observe nanoscale interfacial processes. This information can be used to underpin mechanistic models, which will facilitate new materials design. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101264
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Carbon nanotube-based supercapacitors: breaking the energy density limit. Novel electrodes will be nano-architectured by using ultralong single-walled carbon nanotube arrays and transition metal oxides to produce next-generation supercapacitors. The outcomes will lead to unprecedented energy densities in energy storage devices for sustainable future energy solutions.
Discovery Early Career Researcher Award - Grant ID: DE210101565
Funder
Australian Research Council
Funding Amount
$423,193.00
Summary
An Emerging Ionic Chalcogenide Perovskites for Solar Energy Conversion. This project aims to develop a library of earth-abundant chalcogenide perovskite nanocrystals (CPNCs) for efficient solar energy conversion applications. The key concept is to design non-toxic and stable CPNCs using a facile solution process for solar-to-electricity and fuel generation. The intended outcomes include a fundamental understanding of the relationships between the synthesis, structure, photophysics, and electroch ....An Emerging Ionic Chalcogenide Perovskites for Solar Energy Conversion. This project aims to develop a library of earth-abundant chalcogenide perovskite nanocrystals (CPNCs) for efficient solar energy conversion applications. The key concept is to design non-toxic and stable CPNCs using a facile solution process for solar-to-electricity and fuel generation. The intended outcomes include a fundamental understanding of the relationships between the synthesis, structure, photophysics, and electrochemistry by advanced modeling and multiscale characterizations and ultimately the solar-to-electricity and fuel generation performances of new material systems. This project will build a national research capacity in an emerging field and put Australia at the forefront of practical solar energy conversion technologies.Read moreRead less