Using solar photocatalytic oxidation processes to treat organic pollutants in wastewater. The proposal is to use physical-chemical and solar engineering approaches to increase the efficiency of solar photons in the photocatalytic oxidation process applied to the detoxification of organic pollutants in wastewater. New photocatalyists and the effects of photocatalysts's superficial characteristics on the treatment perfomance will be studied. A specific structure for a solar collector for the proce ....Using solar photocatalytic oxidation processes to treat organic pollutants in wastewater. The proposal is to use physical-chemical and solar engineering approaches to increase the efficiency of solar photons in the photocatalytic oxidation process applied to the detoxification of organic pollutants in wastewater. New photocatalyists and the effects of photocatalysts's superficial characteristics on the treatment perfomance will be studied. A specific structure for a solar collector for the process will be developed. A more efficient way to use solar photons in the process and a better conceptual design of solar collector will be two main outcomes expected from the project.Read moreRead less
Capturing full-spectrum of solar energy using TiO2 ordered suprastructures. The project aims to develop a titanium dioxide (TiO2) semiconductor that can use full-spectrum solar energy. Solar-driven photocatalytic processes have important applications in water decontamination and energy production. Their effectiveness is dictated by the semiconductor’s absorbance and conversion of photoenergy to chemical energy. Being inexpensive, chemically and mechanically robust, TiO2 is the most promising mat ....Capturing full-spectrum of solar energy using TiO2 ordered suprastructures. The project aims to develop a titanium dioxide (TiO2) semiconductor that can use full-spectrum solar energy. Solar-driven photocatalytic processes have important applications in water decontamination and energy production. Their effectiveness is dictated by the semiconductor’s absorbance and conversion of photoenergy to chemical energy. Being inexpensive, chemically and mechanically robust, TiO2 is the most promising material for the semiconductor. However, unmodified TiO2 only absorbs ultraviolet light (5 per cent of solar energy). With current progress made in visible absorbance, this project aims to significantly improve TiO2’s absorbance in near infrared by doping with upconversion lanthanides and rendering colloidal crystal suprastructures that can trap light.Read moreRead less
Exploring the bio-nano interface in plants to enhance crop growth. This project aims to improve the delivery of nutrients and therapeutics to plants by understanding their interactions with nanomaterials. This will create new knowledge on the impact of air, water, and soilborne nanomaterials utilizing cutting-edge bio-nano characterization techniques, innovative lab testing, and high-throughput nanoparticle coating and screening. Expected outcomes of the project include 1) an understanding into ....Exploring the bio-nano interface in plants to enhance crop growth. This project aims to improve the delivery of nutrients and therapeutics to plants by understanding their interactions with nanomaterials. This will create new knowledge on the impact of air, water, and soilborne nanomaterials utilizing cutting-edge bio-nano characterization techniques, innovative lab testing, and high-throughput nanoparticle coating and screening. Expected outcomes of the project include 1) an understanding into how nanomaterial coating technologies impact nanomaterial properties, which will 2) shed light on how nanomaterials interact with plants, which leads to 3) breakthroughs in using nanomaterials to deliver nutrients, fertilizers, and pesticides to boost crop yields and productivity in Australian agriculture.Read moreRead less
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
Discovery Early Career Researcher Award - Grant ID: DE160100796
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Superior Adsorption Capability of Nanosheets for Surface Enhanced Raman. This project aims to create nanotechnologies to sense traces of chemical and biological molecules. Surface adsorption is vital to many scientific and industrial fields, but the intrinsic adsorption property of two-dimensional nanomaterials is largely unknown. This project aims to examine the adsorption capability of nanosheets, such as boron nitride, and understand the thickness effect on their adsorption at the molecular s ....Superior Adsorption Capability of Nanosheets for Surface Enhanced Raman. This project aims to create nanotechnologies to sense traces of chemical and biological molecules. Surface adsorption is vital to many scientific and industrial fields, but the intrinsic adsorption property of two-dimensional nanomaterials is largely unknown. This project aims to examine the adsorption capability of nanosheets, such as boron nitride, and understand the thickness effect on their adsorption at the molecular scale. It also aims to demonstrate the use of these nanosheets as substrates in surface-enhanced Raman spectroscopy. Their adsorption capability and other unique properties could improve the sensitivity, efficiency and affordability of this technique in chemical and biological sensing for applications such as air, water and food safety; and pharmaceutical and cosmetic industries.Read moreRead less
Innovating Smaller, Stronger, Faster Nanoscale Light Sources: SPASERs. The SPASER is a new type of nano-size amplifier which is analogous to a transistor in modern electronics but operates more like a laser. It will be possible to build ultrafast processors of information with SPASERs replacing transistors or can be used in nanosensing, nanoimaging and many other fields. This project will assemble a world-class team consisting of the pioneer of the concept of SPASER and others who developed desi ....Innovating Smaller, Stronger, Faster Nanoscale Light Sources: SPASERs. The SPASER is a new type of nano-size amplifier which is analogous to a transistor in modern electronics but operates more like a laser. It will be possible to build ultrafast processors of information with SPASERs replacing transistors or can be used in nanosensing, nanoimaging and many other fields. This project will assemble a world-class team consisting of the pioneer of the concept of SPASER and others who developed design and analysis techniques in the context of semiconductor lasers and detectors to engineer SPASER design. The aim is to make robust, fast and efficient SPASERs which resembles the features of current lasers for use in circuits in the smallest possible size that consume lowest possible energy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101371
Funder
Australian Research Council
Funding Amount
$459,592.00
Summary
Boron nitride nanosheets for low energy consumption self-cooling devices. This project aims to investigate the thermal transport mechanism of strained two-dimensional materials for self-cooling thermal management. It expects to generate new knowledge about their unique thermal properties, guiding the use of waste heat generated in electronics for self-cooling. Expected outcomes include a novel energy-effective thermal management strategy and enhanced capacity to engineer thermal transport in two ....Boron nitride nanosheets for low energy consumption self-cooling devices. This project aims to investigate the thermal transport mechanism of strained two-dimensional materials for self-cooling thermal management. It expects to generate new knowledge about their unique thermal properties, guiding the use of waste heat generated in electronics for self-cooling. Expected outcomes include a novel energy-effective thermal management strategy and enhanced capacity to engineer thermal transport in two-dimensional materials that will be deployed in miniaturised and high-density electronics to overcome overheating problems. This will provide significant benefits to the economy and the environment, such as reduced cost, energy consumption and CO2 emissions in thermal management technologies. Read moreRead less
Development of Novel Functionalised Two-dimensional Nanomaterials. This project aims to develop a series of novel 2D nanomaterials and their nanocomposites that have applications ranging from energy storage via a functional separator for batteries to thermal management devices. Developing novel functional 2D nanomaterials is important for several applications including energy storage, composite materials, and thermal management, as well as advancing knowledge in the control design of 2D nanomate ....Development of Novel Functionalised Two-dimensional Nanomaterials. This project aims to develop a series of novel 2D nanomaterials and their nanocomposites that have applications ranging from energy storage via a functional separator for batteries to thermal management devices. Developing novel functional 2D nanomaterials is important for several applications including energy storage, composite materials, and thermal management, as well as advancing knowledge in the control design of 2D nanomaterials and to promote the development of sustainable energy storage and thermal management technologies. The benefits to Australia, will be in addressing energy and environmental concerns by developing new clean and environmentally friendly energy devices and boosting national economic growth.Read moreRead less
Two-dimensional transition metal nitrides for energy applications. This project aims to develop novel nanomaterials for sustainable energy applications such as blue energy generation and energy storage. The focus is to explore novel 2D transition metal nitride nanomaterials and their advanced heterostructures with large specific surface area, high electrical conductivity and chemical stability. The expected outcomes include development of high-performance devices such as osmotic energy harvestin ....Two-dimensional transition metal nitrides for energy applications. This project aims to develop novel nanomaterials for sustainable energy applications such as blue energy generation and energy storage. The focus is to explore novel 2D transition metal nitride nanomaterials and their advanced heterostructures with large specific surface area, high electrical conductivity and chemical stability. The expected outcomes include development of high-performance devices such as osmotic energy harvesting devices for blue energy generation and micro-supercapacitors for energy storage. This should promote the growth of sectors in advanced materials, sustainable energy generation, smart energy storage and manufacturing, bringing efficient energy generation and storage system benefits to the Australia and the world.Read moreRead less
Programming soft plasmene nanosheets with living RAFT functional polymers. This project aims to use recently discovered plasmene to demonstrate programmable materials properties using living RAFT polymeric ligands. Plasmene is free-standing, one-particle-thick, superlattice sheets of plasmonic nanoparticles. It represents a conceptually new class of two-dimensional metamaterials with broad applications in energy, environment, sensors and optoelectronic devices. This project expects to generate n ....Programming soft plasmene nanosheets with living RAFT functional polymers. This project aims to use recently discovered plasmene to demonstrate programmable materials properties using living RAFT polymeric ligands. Plasmene is free-standing, one-particle-thick, superlattice sheets of plasmonic nanoparticles. It represents a conceptually new class of two-dimensional metamaterials with broad applications in energy, environment, sensors and optoelectronic devices. This project expects to generate new knowledge and patentable technologies, and advance Australian worldwide standing in the field of nanotechnology and polymer science.Read moreRead less