Hybrid resonant acoustics for microfluidic materials synthesis. This project aims to demonstrate the feasibility of a new class of sound waves as a microfluidic micronisation platform for high throughput particle synthesis and crystallisation of active pharmaceutical ingredients.It will use theoretical and numerical studies to research the fundamental physics of a hybrid between bulk and surface waves. This platform is expected to improve energy efficiency a thousandfold, providing an economical ....Hybrid resonant acoustics for microfluidic materials synthesis. This project aims to demonstrate the feasibility of a new class of sound waves as a microfluidic micronisation platform for high throughput particle synthesis and crystallisation of active pharmaceutical ingredients.It will use theoretical and numerical studies to research the fundamental physics of a hybrid between bulk and surface waves. This platform is expected to improve energy efficiency a thousandfold, providing an economical and environmental alternative to conventional processes such as spray drying, and potentially transforming practice across the pharmaceutical, food and other industries.Read moreRead less
Developing a hybrid waterjet-laser micromachining technology and associated process models for damage-free fabrication of silicon substrates. This hybrid micromachining technology will make it possible for damage-free, fast micro-fabrication of high-integrity devices such as high performance silicon solar cells. It will open new directions for the Australian manufacturing industry in micro-technologies. The environmental and economic benefits to the nation will be highly significant.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100156
Funder
Australian Research Council
Funding Amount
$289,500.00
Summary
3D Two-Photon Nanoprinter for Advanced Multi-Functional Materials & Devices. The Nanoscribe Photonic Professional GT2 Two-Photon 3D Printer enables tailoring materials’ architecture at nanoscale. This results in unique optical, mechanical, electrical, chemical, biochemical, and acoustic properties enabling a wealth of cutting-edge research activities in variety of fields including mechanical/optical/electrical metamaterials, bioinspired hard/soft materials, biomaterials (e.g., structured cell-ti ....3D Two-Photon Nanoprinter for Advanced Multi-Functional Materials & Devices. The Nanoscribe Photonic Professional GT2 Two-Photon 3D Printer enables tailoring materials’ architecture at nanoscale. This results in unique optical, mechanical, electrical, chemical, biochemical, and acoustic properties enabling a wealth of cutting-edge research activities in variety of fields including mechanical/optical/electrical metamaterials, bioinspired hard/soft materials, biomaterials (e.g., structured cell-tissue interfaces), biomedical devices (implantable devices and drug-delivery systems), nanofluidics, and photonic crystals. In each of these fields, we will use GT2 to print variety of polymers, hydrogels, metals and ceramics, for example by printing polymer-derived nanoceramics that will be simultaneously strong and tough.Read moreRead less
A silicon-compatible light source on a silicon-on-insulator platform. Silicon is emerging as an important photonic material owing to the cheap processing methods developed for electronics. This project aims to capture key technology for integrating photonic components onto silicon. It can bring social and commercial benefits to Australia such as high-level research as well as opportunities for commercialisation.
Micromanufacturing and the mechanics of novel composite micro drills. The aim of this project is to develop a novel micromanufacturing technology to produce composite micro drills with desirable properties and reduced production costs. The developed micro drills have significant applications for the printed circuit board industry, medical devices, personal computers, mobile phones and digital cameras. The expected outcomes include optimisation of the micromanufacturing process for improved prope ....Micromanufacturing and the mechanics of novel composite micro drills. The aim of this project is to develop a novel micromanufacturing technology to produce composite micro drills with desirable properties and reduced production costs. The developed micro drills have significant applications for the printed circuit board industry, medical devices, personal computers, mobile phones and digital cameras. The expected outcomes include optimisation of the micromanufacturing process for improved properties of composite micro drills and an enhanced awareness of the mechanics of micromanufacturing composite micro drills to increase reliability in subsequent micro drilling processes. The outcomes have the potential to contribute to the competitiveness of Australia's manufacturing industry.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100688
Funder
Australian Research Council
Funding Amount
$336,446.00
Summary
Nanosensors in artificial cochlea for natural hearing. This project aims to develop a miniaturised and implantable cochlear that closely mimics the human auditory system by utilising advanced microfabrication techniques. This project expects to generate new knowledge in engineering hearing and vestibular hair cells and also on tonotopic organisation of cochlear. Expected outcomes include study of auditory hair cells and development of implantable ear-on-a-chip devices. This project is expected t ....Nanosensors in artificial cochlea for natural hearing. This project aims to develop a miniaturised and implantable cochlear that closely mimics the human auditory system by utilising advanced microfabrication techniques. This project expects to generate new knowledge in engineering hearing and vestibular hair cells and also on tonotopic organisation of cochlear. Expected outcomes include study of auditory hair cells and development of implantable ear-on-a-chip devices. This project is expected to enable low-cost production of highly engineered implant cochlear with great potential for commercialisation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100108
Funder
Australian Research Council
Funding Amount
$175,000.00
Summary
Ultra-high frequency non-contact vibrometry equipment for biomicrofluidics metrology. This equipment will enable experimental vibration measurement up to an unprecedented one billion cycles per second of motion smaller than the width of a helium atom (20 femtometres). Understanding and harnessing the phenomena unique to this regime, especially very large accelerations surpassing one billion times the acceleration of gravity, will enable the development of rapid protein crystallisation techniques ....Ultra-high frequency non-contact vibrometry equipment for biomicrofluidics metrology. This equipment will enable experimental vibration measurement up to an unprecedented one billion cycles per second of motion smaller than the width of a helium atom (20 femtometres). Understanding and harnessing the phenomena unique to this regime, especially very large accelerations surpassing one billion times the acceleration of gravity, will enable the development of rapid protein crystallisation techniques and constant-temperature organic chemical reaction enhancement for rapid development of new drugs, new devices for measuring the profile of surfaces at video speeds (videoAFM), new micro- and nano-devices for fluid pumping, mixing, colloidal separation and concentration, and new autonomous nanorobots for non-invasive microsurgery.Read moreRead less
Hetero-epitaxial silicon carbide: enabling wide-band-gap semiconductors on silicon for greener technologies. In the next decade wide band gap materials will unlock vast potential for a capillary outreach of smart heterogeneous devices, improving energy efficiency and lessening our carbon footprint. This project will aim at major breakthroughs, enabling this pressing technological demand, and putting Australia at the leading edge of this revolution.
Exploiting deep sub-surface temperature-induced phase-transformations for an improved approach to semiconductor laser-dicing. This project aims to explore sub-surface laser-induced phase transformations in semiconductors and to exploit this novel method for ultra-fine laser cutting of semiconductor wafers without debris. The outcomes will be understanding new temperature-induced material modifications and innovative technology development relevant for the semiconductor industry.