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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100168
Funder
Australian Research Council
Funding Amount
$550,000.00
Summary
Integrated Functional Printing Facility for Advanced Material Technologies. The project aims to develop Australia’s first fully integrated small-scale and agile prototyping facility for printing. This facility will provide critical infrastructure to deposit a wide range of advanced materials with unprecedented precision & process flexibility allowing realistic form, configuration and device-ready formats with minimal usage of functional ink. Using this unique facility, researchers will be able t ....Integrated Functional Printing Facility for Advanced Material Technologies. The project aims to develop Australia’s first fully integrated small-scale and agile prototyping facility for printing. This facility will provide critical infrastructure to deposit a wide range of advanced materials with unprecedented precision & process flexibility allowing realistic form, configuration and device-ready formats with minimal usage of functional ink. Using this unique facility, researchers will be able to assess integration of novel functional materials in a wide range of devices and applications, including critical components of affordable healthcare diagnostic devices, advanced security features in banknotes, integrated RFID tracking systems, high performance solar cells and separation membranes. Read moreRead less
Mechanisms and Platforms for Acoustomicrofluidic Intracellular Delivery . This project aims to advance a novel platform to facilitate faster and more effective molecular transport into cells as a means for enhancing cell engineering. Besides elucidating the fundamental physicochemical and biological mechanisms underpinning this new method of intracellular transport through a combination of theoretical modelling and advanced imaging and neutron diffraction, the project aims to show the scalabilit ....Mechanisms and Platforms for Acoustomicrofluidic Intracellular Delivery . This project aims to advance a novel platform to facilitate faster and more effective molecular transport into cells as a means for enhancing cell engineering. Besides elucidating the fundamental physicochemical and biological mechanisms underpinning this new method of intracellular transport through a combination of theoretical modelling and advanced imaging and neutron diffraction, the project aims to show the scalability of the technology for high throughput processing to handle the large cell numbers typically required for doses to be effective in practice. Given recent breakthroughs in cell therapies, it is expected that translation of the technology in the longer term will improve treatments for cancer and other infectious diseases.Read moreRead less
Formation and characterisation of continuous electrospun nanofibre yarns. Australia historically has a strong fibre and textile industry that can be augmented by embracing emerging nanotechnology. The proposed research will develop a technology that can greatly improve the productivity of nanofibres. These fibres can then be spun into continuous yarns and other form of textile products. The nanostructured products offer exceptional functions for biomedical and environmental applications. This ne ....Formation and characterisation of continuous electrospun nanofibre yarns. Australia historically has a strong fibre and textile industry that can be augmented by embracing emerging nanotechnology. The proposed research will develop a technology that can greatly improve the productivity of nanofibres. These fibres can then be spun into continuous yarns and other form of textile products. The nanostructured products offer exceptional functions for biomedical and environmental applications. This new technology has the potential to transform the Australian textile technology and fibre processing industry. Read moreRead less
Acoustomicrofluidic platforms for two-dimensional materials processing. This project aims to exploit high frequency vibration through a novel microfluidic platform for efficiently synthesising and manipulating two-dimensional materials. The project is anticipated to circumvent practical limitations with current synthesis methods, particularly in terms of controllability and reproducibility. The expected outcome is a versatile means for rapidly and uniformly coating these materials on a variety o ....Acoustomicrofluidic platforms for two-dimensional materials processing. This project aims to exploit high frequency vibration through a novel microfluidic platform for efficiently synthesising and manipulating two-dimensional materials. The project is anticipated to circumvent practical limitations with current synthesis methods, particularly in terms of controllability and reproducibility. The expected outcome is a versatile means for rapidly and uniformly coating these materials on a variety of surfaces. Given their remarkable properties, such disruptive technology for consumer/industrial-scale production will provide tremendous opportunities for their application in electronics, energy and catalysis, among other uses.Read moreRead less