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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100075
Funder
Australian Research Council
Funding Amount
$240,000.00
Summary
Fabrication Facility for Oxygen-Sensitive Electronic Materials . Fabrication facility for oxygen-sensitive electronic materials: Turning new materials into functional devices is necessary before their benefits can be widely exploited. This project will provide researchers with a glovebox capability to make devices with materials that are degraded by exposure to oxygen. In particular, the project will use this equipment to make new electronics devices based on organic semiconducting materials, in ....Fabrication Facility for Oxygen-Sensitive Electronic Materials . Fabrication facility for oxygen-sensitive electronic materials: Turning new materials into functional devices is necessary before their benefits can be widely exploited. This project will provide researchers with a glovebox capability to make devices with materials that are degraded by exposure to oxygen. In particular, the project will use this equipment to make new electronics devices based on organic semiconducting materials, investigate oxygen-sensitive materials for energy storage, and undertake fundamental studies of surfaces and interfaces.Read moreRead less
Nanoscale characterisation and manipulation of complex oxide interfaces and topological boundaries. Working at the forefront of complex oxide materials research, this project will explore novel material properties and develop new material application concepts. The project will specifically investigate nanoscale interfaces for potential breakthrough applications in nanoscience.
Rational Design of Novel Multiferroic Materials for Energy Harvesting and Energy Efficiency. Multiferroics are a class of fundamentally complex materials in which several ferroic orders (for example, ferroelectric and ferromagnetic) coexist. The coupling between their electric and magnetic degrees of freedom is controllable via stress and external fields, thus opening the possibility for breakthrough technological developments. By working at the frontier of complex nanostructured oxide materials ....Rational Design of Novel Multiferroic Materials for Energy Harvesting and Energy Efficiency. Multiferroics are a class of fundamentally complex materials in which several ferroic orders (for example, ferroelectric and ferromagnetic) coexist. The coupling between their electric and magnetic degrees of freedom is controllable via stress and external fields, thus opening the possibility for breakthrough technological developments. By working at the frontier of complex nanostructured oxide materials, this project aims to establish the rational basis for systematic design of novel artificially layered multiferroics, develop accurate and computationally affordable methods to simulate these materials under finite-temperature conditions, and exploit this knowledge to devise likely revolutionary photovoltaic, nanoelectronic and energy conversion applications.Read moreRead less
Highly Efficient Solar Window Technology Enabled by Quantum Dots. The transition to zero-greenhouse gas emitting buildings is hindered by the lack of efficient energy generating building components with good aesthetics. This project will develop integrated solar windows that can effectively convert the facades of urban buildings into energy generation sites, enabled by our nanomaterials having outstanding light emission efficiencies of over 90%, accompanied by our advanced light guiding strategi ....Highly Efficient Solar Window Technology Enabled by Quantum Dots. The transition to zero-greenhouse gas emitting buildings is hindered by the lack of efficient energy generating building components with good aesthetics. This project will develop integrated solar windows that can effectively convert the facades of urban buildings into energy generation sites, enabled by our nanomaterials having outstanding light emission efficiencies of over 90%, accompanied by our advanced light guiding strategies and innovative PV cell integration. This next generation technology can reduce the electricity cost and increase renewable energy adoption, placing Australia in a competitive position in the billion-dollar building integrated photovoltaic market whilst also contributing to decarbonising electricity generation.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101100
Funder
Australian Research Council
Funding Amount
$310,000.00
Summary
Nanostructured Cu2ZnSnS4 for solar-driven electricity and hydrogen. This project aims to develop cost-effective Cu2ZnSnS4 nanocrystals for two solar devices for electricity and hydrogen production. The copper-zinc-tin-sulphide (Cu2ZnSnS4) nanoparticle for solar cells has been less than two per cent efficient for years and photoelectrochemical devices have been recently recognised but less explored. The combined innovative modification of its nanocrystals, and grain growth approach for enhancing ....Nanostructured Cu2ZnSnS4 for solar-driven electricity and hydrogen. This project aims to develop cost-effective Cu2ZnSnS4 nanocrystals for two solar devices for electricity and hydrogen production. The copper-zinc-tin-sulphide (Cu2ZnSnS4) nanoparticle for solar cells has been less than two per cent efficient for years and photoelectrochemical devices have been recently recognised but less explored. The combined innovative modification of its nanocrystals, and grain growth approach for enhancing light absorption and photogenerated carrier collection efficiency should elucidate underlying mechanism of and provide solutions to the problem which has baffled researchers in above areas for several years. The intended resulting simple, cost-effective solar-driven electricity and hydrogen devices should make significant contributions to goals of commercially viable storage of solar energy and solutions to global energy and environment issues.Read moreRead less
Hot carrier cooling mechanisms in nano structures. This project aims to systematically investigate possible mechanisms of hot carrier cooling in nano structures and to identify the most dominant mechanisms. These are important for efficient hot carrier solar cells and thermoelectrics. This project will develop new physics to understand hot carrier dynamics in nano structures. This project is expected to result in photovoltaic systems with a lower balance of system and levelised cost of electrici ....Hot carrier cooling mechanisms in nano structures. This project aims to systematically investigate possible mechanisms of hot carrier cooling in nano structures and to identify the most dominant mechanisms. These are important for efficient hot carrier solar cells and thermoelectrics. This project will develop new physics to understand hot carrier dynamics in nano structures. This project is expected to result in photovoltaic systems with a lower balance of system and levelised cost of electricity compared to conventional technologies. This should boost solar industry, create green jobs and reduce greenhouse gas emissions.Read moreRead less
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
Nanoscale control of energy and matter for future energy-efficient technologies. Unprecedented control of energy and matter in nanoscale fabrication will be achieved using non-equilibrium self-organised plasma-solid systems. The outcomes will lead to energy-efficient, environment- and human-health-friendly production of nanomaterials for future energy, health, information, food, water, environmental and security technologies.