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
Discovery Early Career Researcher Award - Grant ID: DE210100692
Funder
Australian Research Council
Funding Amount
$420,000.00
Summary
Multiphysics inertial microfluidics: from fundamentals to applications. Separation of particles and particularly cells is an indispensable process in disease diagnostics, chemical/biological assays and food/chemical industries. This project aims to study the interplay between inertial fluid flow, electricity, and magnetism in microscale for particle separation. The project is expected to establish the fundamental theory underpinning the development of the proposed advanced separation technology. ....Multiphysics inertial microfluidics: from fundamentals to applications. Separation of particles and particularly cells is an indispensable process in disease diagnostics, chemical/biological assays and food/chemical industries. This project aims to study the interplay between inertial fluid flow, electricity, and magnetism in microscale for particle separation. The project is expected to establish the fundamental theory underpinning the development of the proposed advanced separation technology. This disruptive technology is expected to enable the unique, high-performance and high-throughput separation of particles such as cells. The technology will potentially benefit the biomedical and pharmaceutical industries, providing economic opportunities and maintaining high-quality healthcare for Australia.Read moreRead less
A thermodynamic pathway to intracellular delivery. Cells transmit information through molecules. By delivering foreign molecules into cells, such as DNA and proteins, it is possible to engineer and reprogram cells just like a computer. This proposal aims to develop a novel microfluidic device for intracellular delivery. The device will work by exposing cells to rapid thermal shock to generate transient disruptions in cell membranes and thereby enable influx of foreign molecules into cells. To un ....A thermodynamic pathway to intracellular delivery. Cells transmit information through molecules. By delivering foreign molecules into cells, such as DNA and proteins, it is possible to engineer and reprogram cells just like a computer. This proposal aims to develop a novel microfluidic device for intracellular delivery. The device will work by exposing cells to rapid thermal shock to generate transient disruptions in cell membranes and thereby enable influx of foreign molecules into cells. To understand how the method can be optimized, the thermodynamic pathway of membrane disruption will be investigated at a single cell level. The methods and insights arising from this project could eventually lead to novel, patentable and lower-cost health technologies.Read moreRead less
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.
Formation and manipulation of ferroelectric domains with ultrafast light. This project aims to study the fundamental processes governing interaction of ultrafast light pulses with an important class of ferroelectric materials. In particular, it will investigate the physics of light-induced ferroelectric domain reversal in various types of ferroelectrics. Project outcomes will lead to the development of a novel, ultrafast laser domain patterning technique for application in nonlinear photonics, o ....Formation and manipulation of ferroelectric domains with ultrafast light. This project aims to study the fundamental processes governing interaction of ultrafast light pulses with an important class of ferroelectric materials. In particular, it will investigate the physics of light-induced ferroelectric domain reversal in various types of ferroelectrics. Project outcomes will lead to the development of a novel, ultrafast laser domain patterning technique for application in nonlinear photonics, optical memories, and photovoltaics. This technique will be employed to create the first example of three-dimensional domain patterns for versatile wave interactions. This project expects to expand Australia's knowledge in ultrafast laser engineering of materials and contribute towards its rapid uptake by industries, with great potential for commercialisation.Read moreRead less
Magnetofluidic sample handling for enhanced point-of-care diagnosis. This project aims to decipher the mechanism behind recent discovery on the enhancement of mixing and separation with magnetism and to apply it to the rapid and early detection of malaria and cancer. This mechanism provides novel and unique fluid handling capabilities, which allow the development of revolutionary point-of-care diagnostic approaches that integrate magnetic mixing, separation and detection on a single device. The ....Magnetofluidic sample handling for enhanced point-of-care diagnosis. This project aims to decipher the mechanism behind recent discovery on the enhancement of mixing and separation with magnetism and to apply it to the rapid and early detection of malaria and cancer. This mechanism provides novel and unique fluid handling capabilities, which allow the development of revolutionary point-of-care diagnostic approaches that integrate magnetic mixing, separation and detection on a single device. The outcomes of this project are instrumental for the reduction of healthcare cost, promoting good health for Australian and potentially creating new jobs in the niche biomedical industry.Read moreRead less
Towards high-performance wearable devices: materials and microfabrication. This project aims to design and develop functional nanomaterials and nanocomposites for high-performance wearable tactile sensors, integrating the sensors with nanogenerator and charge storage devices. In addition to the functional materials approach, precise control of device architecture through additive manufacturing and laser patterning will be implemented to maximise device performance. The expected outcomes of this ....Towards high-performance wearable devices: materials and microfabrication. This project aims to design and develop functional nanomaterials and nanocomposites for high-performance wearable tactile sensors, integrating the sensors with nanogenerator and charge storage devices. In addition to the functional materials approach, precise control of device architecture through additive manufacturing and laser patterning will be implemented to maximise device performance. The expected outcomes of this project include the detailed understanding of the nanomaterials structural-property relationship under constant mechanical stresses and establishing fundamental principle on the microfabrication of nano device wearable devices. This project will advance the field of materials chemistry and advanced manufacturing with niche high value-added products.Read moreRead less
Ultra-fast alchemy: a new strategy to synthesise super-dense nanomaterials. We have recently created a new super-dense aluminium phase by ultrafast laser microexplosion. This project will search further for new super-dense material phases with drastically different and exotic properties, such as those inside planets and stars, and which have great potential as new nanomaterials for industrial applications.
Discovery Early Career Researcher Award - Grant ID: DE220100205
Funder
Australian Research Council
Funding Amount
$433,000.00
Summary
Engineering micropatterned surfaces for cell mechanics and mechanobiology. This project aims to engineer a highly versatile micropatterned surface that can be used to culture and study cells. This project expects to generate a unique microtechnology, as well as new knowledge in surface science and cell mechanics by elucidating the relationship between controlled surface wettability and cell behaviour. The expected outcomes of this project include a low-cost and highly engineered tissue culture t ....Engineering micropatterned surfaces for cell mechanics and mechanobiology. This project aims to engineer a highly versatile micropatterned surface that can be used to culture and study cells. This project expects to generate a unique microtechnology, as well as new knowledge in surface science and cell mechanics by elucidating the relationship between controlled surface wettability and cell behaviour. The expected outcomes of this project include a low-cost and highly engineered tissue culture tool that controls cellular functions, revolutionising practices in stem cell engineering. The platform technology has a great potential for commercialisation and enhancing Australian research capacity through international and interdisciplinary collaborations and will directly benefit the Australian biotech industry.Read moreRead less
Scaling microfluidics for cell manufacture. Scaling microfluidics for cell manufacture. This project aims to scale microfluidic devices for cell manufacture. Large-scale cell manufacturing processes (cell selection, gene transfer and culture expansion) are expensive, multistep and labour-intensive processes. Lab-on-a-chip devices can automate and integrate these complex processes at microscale. This project will evaluate a prototype bioreactor. This research is expected to make cell therapies ch ....Scaling microfluidics for cell manufacture. Scaling microfluidics for cell manufacture. This project aims to scale microfluidic devices for cell manufacture. Large-scale cell manufacturing processes (cell selection, gene transfer and culture expansion) are expensive, multistep and labour-intensive processes. Lab-on-a-chip devices can automate and integrate these complex processes at microscale. This project will evaluate a prototype bioreactor. This research is expected to make cell therapies cheap enough to become standard treatment, which would benefit patients with diseases that are incurable by conventional therapies (surgery and drug treatments). It should also benefit the Australian advanced manufacturing sector, particularly biopharmaceutical and cell therapy industries.Read moreRead less