Active channel organic transistors. The objective of our project is to create the next generation of electronic transistors based upon organic semiconductors. Specifically, the project will create devices for use in applications such as low power lighting, chemical sensing and lasers.
Structure of Epitaxial Semiconductor Quantum Dots. Epitaxially grown semiconductor quantum dots have received extensive attention in recent years due to their potential applications in electronic and optoelectronic devises. However, the quality of current grown quantum dots is still very far from that required for real device applications due to a lack of detailed knowledge of their nanostructures. This project aims to combine the strength of growing semiconductor quantum dots at Fudan Universit ....Structure of Epitaxial Semiconductor Quantum Dots. Epitaxially grown semiconductor quantum dots have received extensive attention in recent years due to their potential applications in electronic and optoelectronic devises. However, the quality of current grown quantum dots is still very far from that required for real device applications due to a lack of detailed knowledge of their nanostructures. This project aims to combine the strength of growing semiconductor quantum dots at Fudan University and the world-class characterisation facilities (advanced transmission electron microscopy) at the University of Queensland to actively explore optimum paths for epaxially growing device-quality semiconductor quantum dots.Read moreRead less
High Performance Monolithic Perovskite Photocapacitors. Monolithic perovskite photocapacitor (MPPC) consisted of integrated energy harvesting perovskite solar cell and energy storage supercapacitor through an internally shared electrode can deliver stable electricity by harnessing solar energy. The performance of MPPC is dependent of properties of the shared electrode materials. This project aims to synthesis carbon materials with tailored surface, electrical and structure properties that are re ....High Performance Monolithic Perovskite Photocapacitors. Monolithic perovskite photocapacitor (MPPC) consisted of integrated energy harvesting perovskite solar cell and energy storage supercapacitor through an internally shared electrode can deliver stable electricity by harnessing solar energy. The performance of MPPC is dependent of properties of the shared electrode materials. This project aims to synthesis carbon materials with tailored surface, electrical and structure properties that are required to make a highly functioning shared electrode in MPPC. The goal is to fabricate stable, high performance MPPC. Successful achievement of the outcomes will enable cost-effective, reliable, solar electricity, placing Australia at the forefront of exploiting photovoltaics technologies.Read moreRead less
Vapour phase detection of chemical warfare agents. This project aims to create luminescent plastic optoelectronic materials that can detect airborne chemical warfare agents, particularly nerve agents. Such agents are often odourless and invisible at lethal concentrations, so technology must detect and identify them before exposure. The intended outcomes are design rules for sensitive and selective materials that can be used in a handheld infield detector to sense chemical warfare agents based on ....Vapour phase detection of chemical warfare agents. This project aims to create luminescent plastic optoelectronic materials that can detect airborne chemical warfare agents, particularly nerve agents. Such agents are often odourless and invisible at lethal concentrations, so technology must detect and identify them before exposure. The intended outcomes are design rules for sensitive and selective materials that can be used in a handheld infield detector to sense chemical warfare agents based on the materials’ photophysical properties, and new analytical methods and sensing protocols. This research will be of interest to security agencies in Australia and internationally, and will better protect our military.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101156
Funder
Australian Research Council
Funding Amount
$426,476.00
Summary
Preconcentrators for vapour detection of explosive material. This Project’s aim is to develop a preconcentrator technology for the in-field detection of explosive vapours that have low concentrations in air. Low explosive vapour concentration limits the efficacy of portable detectors. Current preconcentrator technologies sorb vapours but require heat to release the concentrated material limiting their use to non-portable detectors. This project is expected to deliver materials and a device modul ....Preconcentrators for vapour detection of explosive material. This Project’s aim is to develop a preconcentrator technology for the in-field detection of explosive vapours that have low concentrations in air. Low explosive vapour concentration limits the efficacy of portable detectors. Current preconcentrator technologies sorb vapours but require heat to release the concentrated material limiting their use to non-portable detectors. This project is expected to deliver materials and a device module for a preconcentrator technology that will sorb explosive analytes, have low power requirements and be compatible with hand held explosives detectors. Security and law enforcement agencies should directly benefit from these findings, which would advance their safety and that of the community as a whole.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100017
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
An integrated system for measuring thermoelectric properties of advanced materials. This facility will establish an integrated measuring system which will form the key step in developing thermoelectric materials. The instruments will support groundbreaking research in developing advanced materials with significant economic and environmental benefits for many industries, such as materials manufacturing and improving automobile energy efficiency.
Discovery Early Career Researcher Award - Grant ID: DE200100448
Funder
Australian Research Council
Funding Amount
$400,116.00
Summary
Developing high-performance GeTe-based thermoelectric materials. This project aims to develop high-performance germanium telluride-based thermoelectric materials by microstructure engineering and band engineering, which will accelerate the drive for eco-friendly energy technology. The outcomes can result in innovative strategies for maximising thermoelectric performance in broader materials and lead to significant progress in knowledge of materials science, solid-state physics, and chemical scie ....Developing high-performance GeTe-based thermoelectric materials. This project aims to develop high-performance germanium telluride-based thermoelectric materials by microstructure engineering and band engineering, which will accelerate the drive for eco-friendly energy technology. The outcomes can result in innovative strategies for maximising thermoelectric performance in broader materials and lead to significant progress in knowledge of materials science, solid-state physics, and chemical science. Thermoelectric devices assembled from as-obtained high-efficiency materials can be used for recovering waste-heat in mining industries and harvesting the waste-heat from engines to improve fuel consumption efficiency, which will strategically boost Australia's energy industry, environment, and economy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101190
Funder
Australian Research Council
Funding Amount
$359,446.00
Summary
Interfacial nano-engineering of electrodes for perovskite solar cells. This project aims to explore new strategies of functional electrode design and interfacial engineering for efficient and stable perovskite solar cell application. The key concept is to modify the electron transport and perovskite layers through structural design, interfacial engineering and contact passivation, for use in high-performance solar-to-electricity conversion systems with improved light harvesting and charge collec ....Interfacial nano-engineering of electrodes for perovskite solar cells. This project aims to explore new strategies of functional electrode design and interfacial engineering for efficient and stable perovskite solar cell application. The key concept is to modify the electron transport and perovskite layers through structural design, interfacial engineering and contact passivation, for use in high-performance solar-to-electricity conversion systems with improved light harvesting and charge collection. Expected project outcomes will place Australia at the forefront of practical low-cost and large-scale solar energy conversion technologies.Read moreRead less
Tailored Biodegradable Polymers for Injection Moulding Applications. This project aims to engineer and scale up production of biodegradable injection molded products with tailored properties, processing and biodegradation. Specifically we will focus on novel materials and processing technologies in tandem with biodegradation understandings to expand the utilization of starch-based polymers. We will then combine fundamental rheological and polymer processing skills with and product development ex ....Tailored Biodegradable Polymers for Injection Moulding Applications. This project aims to engineer and scale up production of biodegradable injection molded products with tailored properties, processing and biodegradation. Specifically we will focus on novel materials and processing technologies in tandem with biodegradation understandings to expand the utilization of starch-based polymers. We will then combine fundamental rheological and polymer processing skills with and product development experience from both universities and the industrial partner (Plantic Technologies) to scale up processing and develop successful biodegradable products. This project will also enable an Australian owned start-up company with a broad shareholder base to generate significant export income through key commercialization.Read moreRead less