Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100090
Funder
Australian Research Council
Funding Amount
$1,136,244.00
Summary
Xe-plasma dual beam for advanced future materials. This project aims to establish a state of the art Xe-Plasma dual-beam facility providing characterisation and fabrication capabilities to Australia’s research community. The project will use two beams - one Xe, the other electrons - to mill the surface of bulk materials which are subsequently analysed by electron or ion beam techniques to determine atomic-scale microstructure(s) and compositions. Anticipated outcomes are advanced materials engin ....Xe-plasma dual beam for advanced future materials. This project aims to establish a state of the art Xe-Plasma dual-beam facility providing characterisation and fabrication capabilities to Australia’s research community. The project will use two beams - one Xe, the other electrons - to mill the surface of bulk materials which are subsequently analysed by electron or ion beam techniques to determine atomic-scale microstructure(s) and compositions. Anticipated outcomes are advanced materials engineering and new knowledge about ancient and future materials. This is expected to provide significant advances across a variety of fields including material science, engineering and geology and enhance trans-disciplinary collaborations.Read moreRead less
Enhanced sensitivity of electrospray ionization mass spectrometry. Enhanced sensitivity of electrospray ionization mass spectrometry. This project aims to enhance the sensitivity of nano-electrospray ionization mass spectrometry (nanoESI-MS) by an order of magnitude by simultaneously overcoming the two interdependent limitations in ion generation and transmission efficiency. This project will design glass capillaries and tubes with complex structures to enable both multiplexing ion generation fr ....Enhanced sensitivity of electrospray ionization mass spectrometry. Enhanced sensitivity of electrospray ionization mass spectrometry. This project aims to enhance the sensitivity of nano-electrospray ionization mass spectrometry (nanoESI-MS) by an order of magnitude by simultaneously overcoming the two interdependent limitations in ion generation and transmission efficiency. This project will design glass capillaries and tubes with complex structures to enable both multiplexing ion generation from a single capillary and geometrically matching the bore of the tube collecting the emitted ion plume. NanoESI-MS has become an indispensable analytical tool for proteomics and synthetic chemistry. The significant enhancement of nanoESI-MS sensitivity in this project is expected to accelerate progress in disease research, biomarker discovery and drug development.Read moreRead less
Dynamic substrates for surface-enhanced Raman scattering: piezoelectric actuated nanotextures with phase-locked signal processing. Surface-enhanced Raman scattering shows great promise for sensitive detection of a wide range of chemical and biological compounds. Novel electronic devices will be produced to actively tune the nanometre scale structures that generate the scattering signal, resulting in an improved fundamental understanding and control of the effect.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100094
Funder
Australian Research Council
Funding Amount
$220,000.00
Summary
Macromolecular characterisation and purification facility. In-depth characterisation of (bio)macromolecules and nanomaterials is fundamental to understanding their properties and application to advanced materials and technologies. The three new instruments at this facility dedicated to the purification, separation and characterisation of these compounds will provide an essential resource for polymer/materials research.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100087
Funder
Australian Research Council
Funding Amount
$410,000.00
Summary
Advanced Macromolecular Materials Characterisation Facility (AMMCF). Advanced macromolecular materials characterisation facility: The facility will allow precise characterisation of (bio)macromolecular materials, from chemical structures and composition as a function of size or biodistribution, to film thickness in multi-layer materials, to material hydrophobicity and permeability. Novel information derived from these state-of-the-art instruments is highly valuable in understanding structure-pro ....Advanced Macromolecular Materials Characterisation Facility (AMMCF). Advanced macromolecular materials characterisation facility: The facility will allow precise characterisation of (bio)macromolecular materials, from chemical structures and composition as a function of size or biodistribution, to film thickness in multi-layer materials, to material hydrophobicity and permeability. Novel information derived from these state-of-the-art instruments is highly valuable in understanding structure-property relationships, which are crucial for the development of the next generation of advanced materials with applications in electronics, optics, sensors, membranes, nanocoatings, biomaterials and polymer therapeutics. This facility underpins the efforts of the participating institutes in increasing the quality and quantity of research outcomes.Read moreRead less
Replicating the cartilage micromechanical environment. Through a novel, image-guided mechanical evaluation of cell- and tissue-level remodelling, this project aims to unlock new insights into the complex mechanical microenvironment of cartilage and directly influence new strategies in tissue engineering. The research will reveal contributions of cells and extracellular matrix components to mechanical integrity over time. It will build a world-first strain map of the cartilage microenvironment an ....Replicating the cartilage micromechanical environment. Through a novel, image-guided mechanical evaluation of cell- and tissue-level remodelling, this project aims to unlock new insights into the complex mechanical microenvironment of cartilage and directly influence new strategies in tissue engineering. The research will reveal contributions of cells and extracellular matrix components to mechanical integrity over time. It will build a world-first strain map of the cartilage microenvironment and quantification of dynamic structural remodelling that occurs, providing key targets to improve tissue engineering strategies. The project will also drive innovation in micromechanical testing technology, deliver functional solutions in mechanobiology and advance materials for biological integration.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100016
Funder
Australian Research Council
Funding Amount
$490,000.00
Summary
Multi-scale fabrication facility for complex three-dimensional surface generation from nano to macro dimensions. This facility will support advances in the manufacturing of free-form surfaces with submicron features. Its unique characteristics, such as the universal profiling ability and nanometre accuracy across large dimensions, will enable many science and engineering innovations which are presently impossible to be realised in Australia.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100094
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Development of a world-class facility for three dimensional dynamic testing. Development of a world-class facility for three dimensional dynamic testing: This project aims to establish a world-class facility for multi-directional dynamic testing. Currently there are no such facilities in Australia. The ability to recreate dynamic motion in all available degrees-of-freedom opens up enormous fields of research not currently possible in Australia. This includes such areas as vibration testing, mate ....Development of a world-class facility for three dimensional dynamic testing. Development of a world-class facility for three dimensional dynamic testing: This project aims to establish a world-class facility for multi-directional dynamic testing. Currently there are no such facilities in Australia. The ability to recreate dynamic motion in all available degrees-of-freedom opens up enormous fields of research not currently possible in Australia. This includes such areas as vibration testing, materials testing, biomechanics and human factors, blast and earthquake simulations, field robotics, automotive safety research, flight/vehicle simulation, and marine applications including sloshing of liquids and liquefaction of fines. In conjunction with a 3D laser doppler system this facility will be unique in the world for dynamic mechanical testing.Read moreRead less
Photoacoustic cellular manipulation: building from the bottom up. In this project we propose an approach for creating complex 3D prints. Whereas current approaches are limited to defining the external geometry, this technology will permit the organization of the internal structure as well, with the potential to do so at the scale of individual cells. Achieving this has important applications in bioprinting human tissues and additive manufacturing. This is based on the manipulation of particles a ....Photoacoustic cellular manipulation: building from the bottom up. In this project we propose an approach for creating complex 3D prints. Whereas current approaches are limited to defining the external geometry, this technology will permit the organization of the internal structure as well, with the potential to do so at the scale of individual cells. Achieving this has important applications in bioprinting human tissues and additive manufacturing. This is based on the manipulation of particles and cells using holographic acoustic fields controlled by patterned light. This is compared to current acoustic patterning approaches are mostly limited to static simple geometric arrangements and lack the flexibility to produce arbitrary, rapidly changing fields that enable the fabrication of complex structures. Read moreRead less
New generation microfluidic devices using light responsive hydrogels. This project aims to develop a new way of fabricating microfluidic devices using light-degradable hydrogels as its core element. This approach would allow researchers to rapidly construct and modify microfluidic devices within their own laboratories, without the need for specialised clean rooms or expensive equipment. The versatility of the microfluidic device is designed to be demonstrated by the manufacture of mature T cells ....New generation microfluidic devices using light responsive hydrogels. This project aims to develop a new way of fabricating microfluidic devices using light-degradable hydrogels as its core element. This approach would allow researchers to rapidly construct and modify microfluidic devices within their own laboratories, without the need for specialised clean rooms or expensive equipment. The versatility of the microfluidic device is designed to be demonstrated by the manufacture of mature T cells, which continues to be a major challenge in stem cell science and which could have fundamental biological and commercial significance.Read moreRead less