Flow physics of porous wall fuel injection for scramjet combustion and drag reduction. This project combines world-class Australian scramjet science with German advanced high temperature materials, exploring potentially transformational technology for satellite launch. Australia’s credentials in the international space arena will strengthen, contributing to assured access to the space-based applications upon which we heavily depend.
The science of scramjet propulsion. This project will study the science of scramjet operation at high Mach numbers and develop the understanding required for operation at such conditions. The outcomes include experimentally validated scramjet models operating at speeds never reached before, and the potential to extend the known flight envelope for air breathing propulsion.
Discovery Early Career Researcher Award - Grant ID: DE120102277
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Design optimisation and physical behaviour of fuel injection and mixing for innovative scramjet concepts. Scramjets are a potential game changer for satellite launch and high speed flight. The phenomena that will make or break them are complex, and achieving optimal designs is hugely challenging. This project combines advanced optimisation techniques and flow simulations to find, and understand, optimal fuel injection for innovative scramjet designs.
Discovery Early Career Researcher Award - Grant ID: DE140100932
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Hypervelocity Roughness-Induced Laminar-Turbulent Transition for Advanced Scramjet Flow Control. Scramjet technology is set to make air-breathing flight beyond five times the speed of sound a reality. At such speeds, complex aerodynamic phenomena are likely to cause flow separation in the scramjet, hence significantly affecting its operability. This project will establish the applicability of discrete surface micro-roughness elements to induce the laminar-turbulent transition of hypervelocity bo ....Hypervelocity Roughness-Induced Laminar-Turbulent Transition for Advanced Scramjet Flow Control. Scramjet technology is set to make air-breathing flight beyond five times the speed of sound a reality. At such speeds, complex aerodynamic phenomena are likely to cause flow separation in the scramjet, hence significantly affecting its operability. This project will establish the applicability of discrete surface micro-roughness elements to induce the laminar-turbulent transition of hypervelocity boundary layers, with the purpose of energising the surface flow entering the engine so that it can sustain higher adverse pressure gradients without separating. This project will undertake a targeted ground test program to characterise the physical mechanisms of hypervelocity roughness-induced laminar-turbulent transition.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100229
Funder
Australian Research Council
Funding Amount
$230,000.00
Summary
Carbon-free high temperature vacuum sintering facility. This facility will provide an extremely clean sintering environment for development of advanced materials free from imperfections for applications which range from energy conversion to medical components. It will ensure that Australia is an important international leader in both fundamental research and industrial innovation.
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
Experimental validation of the strain invariant failure theory for carbon/epoxy composites. The project will be of national and international benefit, through providing a validated, enhanced design capability for advanced composite materials. Greater depth of understanding of such materials will allow more efficient structures to be designed in applications requiring high strength and stiffness, low weight, and resistance to corrosion and fatigue. Such applications include the aerospace, offshor ....Experimental validation of the strain invariant failure theory for carbon/epoxy composites. The project will be of national and international benefit, through providing a validated, enhanced design capability for advanced composite materials. Greater depth of understanding of such materials will allow more efficient structures to be designed in applications requiring high strength and stiffness, low weight, and resistance to corrosion and fatigue. Such applications include the aerospace, offshore and mining industries. There are, therefore, far-reaching benefits in industries important to Australia. In addition, the reputation of the Australian aerospace research industry will be promoted through a collaborative association with Boeing, a world leader in development of commercial aircraft.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100194
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Optical diagnostics for the investigation of high-speed energetic processes. Optical diagnostics for the investigation of high-speed energetic processes:
The project seeks to establish equipment to enable the investigation of high-speed energetic processes. Such processes, where large amounts of energy are released over a short time frame, occur in nature and almost every field of science and engineering, and their investigation is a formidable challenge. This challenge is designed to be met th ....Optical diagnostics for the investigation of high-speed energetic processes. Optical diagnostics for the investigation of high-speed energetic processes:
The project seeks to establish equipment to enable the investigation of high-speed energetic processes. Such processes, where large amounts of energy are released over a short time frame, occur in nature and almost every field of science and engineering, and their investigation is a formidable challenge. This challenge is designed to be met through the combined use of state-of-the-art flow visualisation, thermography and spectrometry equipment. These diagnostics would open avenues into so far impossible or difficult to conduct research on highly transient phenomena in various research fields, which include various aspects of fluid mechanics, combustion, and fracture mechanics. The equipment would be instrumental in the design of better and innovative machines, materials, instruments and processes.Read moreRead less
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.
Controllable growth of magnetic semiconductor quantum dots for future spintronic and optoelectronic devices. This project aims to develop high quality magnetic semiconductor materials for next generation magnetic and optoelectronic devices. Outcomes of this project will lead to advanced applications in light-emitting diodes and information technology, such as high density hard drivers and low dissipation quantum computers.