Australian Laureate Fellowships - Grant ID: FL210100017
Funder
Australian Research Council
Funding Amount
$3,115,000.00
Summary
Nanoscale-interactions making future functional materials more powerful . Traditional crystal chemistry can no longer meet the demands for development of new functional materials - the foundation of modern industry. The program aims to overcome this challenge by introducing a new strategy into experimental and theoretical research to transform our understanding and application of nanoscale structural and chemical features in materials. The program expects to build new crystal chemistry that incl ....Nanoscale-interactions making future functional materials more powerful . Traditional crystal chemistry can no longer meet the demands for development of new functional materials - the foundation of modern industry. The program aims to overcome this challenge by introducing a new strategy into experimental and theoretical research to transform our understanding and application of nanoscale structural and chemical features in materials. The program expects to build new crystal chemistry that includes nanoscale-interaction information and deep machine-learning to improve the predictability of material properties. Potential outcomes of the program include enhanced capacity for revolutionary materials development thus keeping Australia's leading position in innovative technology, benefiting academia and industry.Read moreRead less
Understanding and controlling of photoferroelectricity for photoenergy uses. The project seeks to develop high performance photoferroelectric materials for a wide range of photoenergy conversion technologies like photovoltaics and photocatalytics. For the past 50 years, ferroelectric photovoltaics have only been an academic curiosity due to their low energy conversion efficiency relative to the popular semiconductor photovoltaics. This project aims to unlock the potential of ferroelectric photov ....Understanding and controlling of photoferroelectricity for photoenergy uses. The project seeks to develop high performance photoferroelectric materials for a wide range of photoenergy conversion technologies like photovoltaics and photocatalytics. For the past 50 years, ferroelectric photovoltaics have only been an academic curiosity due to their low energy conversion efficiency relative to the popular semiconductor photovoltaics. This project aims to unlock the potential of ferroelectric photovoltaics by introducing an ion co-substitution, which is coupled with electron-pinning, into promising ferroelectric materials and investigating the resultant photo-excited electronic and electrical properties. It is anticipated that the outcomes from this proposed project will provide a solution for optimal ferroelectric visible light absorption to achieve high power conversion efficiency in ferroelectric materials for practical photoenergy applications.Read moreRead less
Ferroelectric piezoelectric materials and key problems associated with their applications in mechanical, electrical and optical energy transformations. This project aims to investigate the dynamic microstructure of ferroelectric piezoelectric materials in response to electrical fields or mechanical stresses, and therefore identify the factors enhancing the mechanical, electrical and optical couplings for intentional improvement and development of these materials for use in energy transformations ....Ferroelectric piezoelectric materials and key problems associated with their applications in mechanical, electrical and optical energy transformations. This project aims to investigate the dynamic microstructure of ferroelectric piezoelectric materials in response to electrical fields or mechanical stresses, and therefore identify the factors enhancing the mechanical, electrical and optical couplings for intentional improvement and development of these materials for use in energy transformations.Read moreRead less
Probing anti-ferroelectric to ferroelectric structural phase transitions: towards high power energy transformation devices. Materials which can be rapidly switched from anti-ferroelectric to ferroelectric states exhibit a wide range of exploitable properties. This project will identify the factors enabling such materials to respond to applied electric fields and mechanical stresses and use them to enhance the ability of industry to develop new advanced materials.
Doped metal perovskites for electrocatalysis. This project aims to discover and design perovskite metal-oxide electrocatalyst materials and develop electrocatalytic methods for efficiently driving the oxygen evolution reaction and the oxygen reduction reaction. These are the two most crucial reactions in sustainable energy cycles involving water, hydrogen and oxygen. The project’s anticipated advances in electrocatalysis efficiency for these two reactions will benefit sustainable energy technolo ....Doped metal perovskites for electrocatalysis. This project aims to discover and design perovskite metal-oxide electrocatalyst materials and develop electrocatalytic methods for efficiently driving the oxygen evolution reaction and the oxygen reduction reaction. These are the two most crucial reactions in sustainable energy cycles involving water, hydrogen and oxygen. The project’s anticipated advances in electrocatalysis efficiency for these two reactions will benefit sustainable energy technologies such as fuel cells, metal air batteries and water splitting.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100170
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
A tuneable femtosecond light source for materials and biological sciences. Researchers at The Australian National University, Monash University and The University of Technology, Sydney are involved in a range of projects where new molecules are synthesised or discovered in nature. Molecules like these have applications in new photonics or energy technologies. This integrated facility will afford intense light of varying pulse durations to investigate the behaviour and performance of such molecul ....A tuneable femtosecond light source for materials and biological sciences. Researchers at The Australian National University, Monash University and The University of Technology, Sydney are involved in a range of projects where new molecules are synthesised or discovered in nature. Molecules like these have applications in new photonics or energy technologies. This integrated facility will afford intense light of varying pulse durations to investigate the behaviour and performance of such molecules.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100635
Funder
Australian Research Council
Funding Amount
$373,170.00
Summary
Inks for the fabrication of thin-film photovoltaic devices by solution processable deposition techniques. Due to their high cost the current generation of solar cells has had limited uptake into the market place. With the use of nanoparticle inks that can form light absorbing layers, solar cells may be fabricated cheaply in the future with solution-based manufacturing techniques, such as spray coating or printing.
Benchmarking of advanced scattering probes for materials characterisation. The project seeks to establish the accuracy and validity of different methods of nanoscale structure determination. Nanoscale structure is crucial to the properties of many modern materials with diverse applications: e.g. sensors and actuators in cell phones; smart shock absorbers and fuel injectors in cars; memory devices; drug delivery devices.
Engineered nanoassmblies for energy conversion. This research will lead to development of clean energy technology that can compete with the traditional energy sources without subsidies, and facilitate long-term solution to the energy crisis and global warming. It will also bring significant benefit to Australian industries and economy and assist achievement of renewable energy target.
Responsive porous materials for the triggered release of stored target molecules. This project will create a new generation of ultraporous materials capable of releasing a valuable molecule, stored within their pores, when an external trigger is applied. The porous materials, including metal organic frameworks and porous aromatic frameworks, will have components incorporated within them that can respond to stimuli such as ultraviolet or visible light, microwave, ultrasound, or pH change, causing ....Responsive porous materials for the triggered release of stored target molecules. This project will create a new generation of ultraporous materials capable of releasing a valuable molecule, stored within their pores, when an external trigger is applied. The porous materials, including metal organic frameworks and porous aromatic frameworks, will have components incorporated within them that can respond to stimuli such as ultraviolet or visible light, microwave, ultrasound, or pH change, causing the stored target molecule to be released. Target molecules will include carbon dioxide, fertilisers, clean burning gaseous fuels and medicines.Read moreRead less