Discovery Early Career Researcher Award - Grant ID: DE200100279
Funder
Australian Research Council
Funding Amount
$424,198.00
Summary
A nanodiamond voltage sensor: towards real-time, long-term neuronal sensing. This project aims to develop a voltage sensor that may ultimately be used to measure neuronal signals noninvasively in real-time and over hours. The project expects to generate the fundamental science needed to use nanodiamonds for fluorescence-based voltage sensing that can be easily measured using optical microscopy. The expected outcome is a biocompatible sensor that should provide a solution to one of the biggest ch ....A nanodiamond voltage sensor: towards real-time, long-term neuronal sensing. This project aims to develop a voltage sensor that may ultimately be used to measure neuronal signals noninvasively in real-time and over hours. The project expects to generate the fundamental science needed to use nanodiamonds for fluorescence-based voltage sensing that can be easily measured using optical microscopy. The expected outcome is a biocompatible sensor that should provide a solution to one of the biggest challenges in neuroscience; the fast, precise and long-term measurement of neuronal activity. This technology may one day inform our understanding of how the normal brain works and provide major insights into mental health conditions and neurodegenerative diseases.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100169
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Ultraviolet, visible and infrared spectroscopic ellipsometers for advanced materials and device characterisation. The ellipsometers at this facility will enable optical characterisation of several advanced materials in the wide spectral range of 250 nanometres - 30 micrometres. As well as refractive index and thickness measurement, they will provide absorption spectroscopy which will allow assessment of novel glasses and surface functionalisation approaches for the optimisation of new sensing te ....Ultraviolet, visible and infrared spectroscopic ellipsometers for advanced materials and device characterisation. The ellipsometers at this facility will enable optical characterisation of several advanced materials in the wide spectral range of 250 nanometres - 30 micrometres. As well as refractive index and thickness measurement, they will provide absorption spectroscopy which will allow assessment of novel glasses and surface functionalisation approaches for the optimisation of new sensing technologies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101721
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Probing the excited states of organic semiconductor systems with photoinduced absorption spectroscopy. Plastic semiconductors have the potential to revolutionise consumer electronics by enabling cheap, flexible and low power devices. The success of these devices depends on our understanding of the optical and electronic properties of the materials, which this project aims to address through the use of photoinduced absorption spectroscopy.
Photonic circuitry from the noble metals: nanocrystal coupling. Linear arrays of crystalline nanoparticles are able to act in a manner analogous to an optical fibre, but with much smaller dimensions. This project will investigate the underlying principles of waveguiding within the arrays and aims to build and test sections of such optical fibres, thereby assessing their use in optical circuits.
Harnessing Asymmetry in Hybrid Metal Nanocrystal Assemblies. The interaction between metallic nanoparticles creates highly enhanced, localised electric fields and has recently emerged as a strategic area widely applicable across physics, chemistry and biology for sensing, optoelectronics and optical films. The novel optical signatures of larger, highly symmetric nanoparticle assemblies may be drastically changed by breaking the structural symmetry, leading to unique phenomenon such as Fano-like ....Harnessing Asymmetry in Hybrid Metal Nanocrystal Assemblies. The interaction between metallic nanoparticles creates highly enhanced, localised electric fields and has recently emerged as a strategic area widely applicable across physics, chemistry and biology for sensing, optoelectronics and optical films. The novel optical signatures of larger, highly symmetric nanoparticle assemblies may be drastically changed by breaking the structural symmetry, leading to unique phenomenon such as Fano-like resonances. This project aims to extend metal nanoparticle assemblies to include fluorophores in well-defined positions, creating an inherent and switchable symmetry breaking. Inclusion of additional functionality into such structures is essential for their use in smart optical films and switchable devices.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100107
Funder
Australian Research Council
Funding Amount
$415,000.00
Summary
Time-resolved terahertz and optical spectroscopy facility. Time-resolved terahertz and optical spectroscopy facility:
This project aims to use time-resolved terahertz and optical spectroscopy as techniques to probe the photogenerated exciton and charge carrier dynamics at the heart of solar energy technologies. The dynamics of electrons and nuclei following the absorption of light involves processes which occur on timescales from femtoseconds to microseconds. The ability to probe these dynamics ....Time-resolved terahertz and optical spectroscopy facility. Time-resolved terahertz and optical spectroscopy facility:
This project aims to use time-resolved terahertz and optical spectroscopy as techniques to probe the photogenerated exciton and charge carrier dynamics at the heart of solar energy technologies. The dynamics of electrons and nuclei following the absorption of light involves processes which occur on timescales from femtoseconds to microseconds. The ability to probe these dynamics is of great importance for understanding the underlying photophysics and photochemistry of a range of technologies including solar photovoltaics and solar photocatalysis. This facility would enable researchers to deeply understand the photophysical processes occurring in advanced photovoltaic and photocatalysis materials and devices and may facilitate the development of advanced materials for renewable energy. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100151
Funder
Australian Research Council
Funding Amount
$302,154.00
Summary
Near infrared imaging and spectroscopy facility. This project will establish a cutting-edge optical microscopy platform using light just beyond our vision, in the near-infrared. Recent developments in near-infrared camera technology have opened up new opportunities for applications in this under-explored spectral region. Expected outcomes include the development of new methods for harvesting near-infrared sunlight and for photocatalysis of solar fuels, new biomimetic coatings for thermal managem ....Near infrared imaging and spectroscopy facility. This project will establish a cutting-edge optical microscopy platform using light just beyond our vision, in the near-infrared. Recent developments in near-infrared camera technology have opened up new opportunities for applications in this under-explored spectral region. Expected outcomes include the development of new methods for harvesting near-infrared sunlight and for photocatalysis of solar fuels, new biomimetic coatings for thermal management, new security signatures invisible to the naked eye, new materials for phototherapy, and improved techniques for imaging biological samples. It will benefit Australian renewable energy, security, building, and biomedical industries, and train our next generation of optical science researchers.Read moreRead less
Deep-ultraviolet light source by frequency doubling of blue or green light for disinfection. Current ultraviolet light sources are inefficient and often bulky. By an alternative approach, in which the wavelength of blue or green light is halved, this project will design and build compact, efficient sources of ultraviolet light, which can be used for disinfection and sterilization. Such devices can be fabricated by Australian industry in Australia.
Conducting nanoporous materials: toward molecular devices. This project addresses one of the foremost challenges in the field of advanced functional materials, namely the design and synthesis of nanoporous materials that conduct electrons. The outcomes on both a fundamental and applied level will pave the way toward molecular electronics devices for solid-state sensing to solar energy harvesting.
Nanoparticle inks for electronic applications employing nanostructured thin-films. The development of next-generation technologies requires careful engineering of materials at the nanoscale. Using nanoparticle inks, many of the engineering difficulties which exist at these length scales can be overcome, thus allowing for technologies such as thin-film solar cells to become cheaper and more efficient.