Discovery Early Career Researcher Award - Grant ID: DE120101329
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Ultra-stable photonic-chip pulse source. An ultra-low noise high repetition photonic-chip pulse source is proposed. This ultra-stable device offers orders-of-magnitude improvements over existing solutions and holds potential for strong improvements to analogue-to-digital converters. The laser will be a crucial component for photonic integrated circuits, enabling millimetre size processing.
Multi-colour ultrashort soft X-ray pulses. This project aims to create multi-colour, ultrashort, highly coherent, bright pulses of soft X-rays based on high-harmonic generation in a table-top multiple-section gas cell. Studying multi-electronic and non-adiabatic processes and other fundamental aspects such as multi-electronic correlations and non-Born-Oppenheimer vibronic couplings in complex molecules is a major challenge in current ultrafast photochemistry research. This project will use multi ....Multi-colour ultrashort soft X-ray pulses. This project aims to create multi-colour, ultrashort, highly coherent, bright pulses of soft X-rays based on high-harmonic generation in a table-top multiple-section gas cell. Studying multi-electronic and non-adiabatic processes and other fundamental aspects such as multi-electronic correlations and non-Born-Oppenheimer vibronic couplings in complex molecules is a major challenge in current ultrafast photochemistry research. This project will use multiple driving pulses with different carrier frequencies to control the spectral properties and time delay of the pulses. It will use the soft X-ray source to develop an ideal platform for studying multi-electronic and non-adiabatic processes, multi-electronic correlations and non-Born-Oppenheimer vibronic couplings in complex molecules. This is expected to advance materials science, paving the way to soft X-ray technologies.Read moreRead less
Brillouin processing for carrier recovery in optical communications. This project aims to apply Brillouin processing to the development of an innovative, self-tracking optical filter for isolating optical carriers in the coherent receiver of future ultrahigh bit-rate optical communication systems. By recovering a needle-like optical carrier with great precision from a drifting sea of wide-band noise and data channels, the project expects to minimise the effect of optical carrier distortions on t ....Brillouin processing for carrier recovery in optical communications. This project aims to apply Brillouin processing to the development of an innovative, self-tracking optical filter for isolating optical carriers in the coherent receiver of future ultrahigh bit-rate optical communication systems. By recovering a needle-like optical carrier with great precision from a drifting sea of wide-band noise and data channels, the project expects to minimise the effect of optical carrier distortions on the data-carrying signals. The project should advance knowledge in optical signal processing and communications technologies, with outcomes that increase the data-carrying capacity of optical networks. Future telecommunication networks should benefit through improved transmission rates and extended fibre links.Read moreRead less
Optically-activatable nanolithography for ultralow energy long data storage. This project aims to investigate greenphotonic long data storage. Optically-activated nanolithography that adopts earth abundant lanthanide-doped nanoparticles and vectorial holography could enable the development of ultra-long lifetime, ultra-low energy consumption, and ultra-fast access speed technology platforms for exabyte big data centres. The research discoveries from this project will enable the greenphotonic lon ....Optically-activatable nanolithography for ultralow energy long data storage. This project aims to investigate greenphotonic long data storage. Optically-activated nanolithography that adopts earth abundant lanthanide-doped nanoparticles and vectorial holography could enable the development of ultra-long lifetime, ultra-low energy consumption, and ultra-fast access speed technology platforms for exabyte big data centres. The research discoveries from this project will enable the greenphotonic long data storage technology, reducing energy consumption. Such a breakthrough would provide a key platform for the emerging industry revolution 4.0 and build Australia’s international leadership in green and smart digital economies in the big data era.Read moreRead less
Tuning the multiplexing of optical angular momentum with graphene photonics. This project aims to develop a conceptually new graphene nano-device that allows for tuning the multiplexing of optical angular momentum from the near-infrared to mid-infrared wavelength regions. The innovation of this project is nano-engineering of the cutting-edge graphene-on-silicon technology in designing the world-first tunable optical-angular-momentum multiplexer for on-chip integration. This project will result i ....Tuning the multiplexing of optical angular momentum with graphene photonics. This project aims to develop a conceptually new graphene nano-device that allows for tuning the multiplexing of optical angular momentum from the near-infrared to mid-infrared wavelength regions. The innovation of this project is nano-engineering of the cutting-edge graphene-on-silicon technology in designing the world-first tunable optical-angular-momentum multiplexer for on-chip integration. This project will result in a new horizon of ultra-high-capacity chip-scale devices which can enable the new applications including wireless optical communications and thus accelerate the realisation of the emerging LiFi-based big data technology platform.Read moreRead less
Quantum effects in photosynthesis: responsible for highly efficient energy transfer or trivial coincidence? Understanding the precise details of the highly efficient energy transfer processes in photosynthesis has the potential to impact the design of efficient solar energy solutions. This project will gain this understanding by exploring the nature of interactions between different components and the significance of quantum mechanics.
Quantitative multidimensional optical spectroscopy: revealing dynamics and structure in complex condensed matter systems. Understanding how quantum mechanics affects photosynthesis and how it can cause interactions between distant nanostructures are intriguing problems that may be of great significance for future smart technologies. This project will gain unprecedented insight into these processes using a novel technique to identify and resolve the mechanisms responsible.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100137
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Femtosecond broad wavelength range laser facility. This facility will provide a unique source of ultra-short laser pulses spanning the X-ray to the infrared regions. It will provide a powerful coherent X-ray source that will position Australia at the forefront of coherent imaging science and the ability to perform ultrafast infrared spectroscopic measurements.