Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100184
Funder
Australian Research Council
Funding Amount
$183,437.00
Summary
Femtoliter Liquid Deposition Facility. This project aims to create a research capacity for direct printing of femtolitre volumes of functional liquids onto devices and surfaces. This project expects to enable the development of new sensing and electronic devices that require a novel fabrication step with delicate materials that cannot be deposited using existing processes. Expected outcomes include new chemical and biological sensors created through collaborative research between the partner in ....Femtoliter Liquid Deposition Facility. This project aims to create a research capacity for direct printing of femtolitre volumes of functional liquids onto devices and surfaces. This project expects to enable the development of new sensing and electronic devices that require a novel fabrication step with delicate materials that cannot be deposited using existing processes. Expected outcomes include new chemical and biological sensors created through collaborative research between the partner institutions and researchers. The benefits of this project should include the creation of a new rapid prototyping facility for Australian researchers, and the application of these capabilities for the development of new low-cost sensors for environmental gas sensing and glucose monitoring.Read moreRead less
Integrated on-chip force and displacement sensors for high-speed atomic force microscopy of ultimate sensitivity. This project aims to develop next generation atomic force microscopy systems based on a novel interferometric method for on-chip force and displacement sensing. The proposed sensitivity improvement of two orders of magnitude over the present state-of-the-art will provide a disruptive innovation for various present and future nanotechnologies.
Towards a unified technology platform for sensing in liquids. Towards a unified technology platform for sensing in liquids. This project aims to use a new sensing platform for hydrocarbon monitoring in water to evolve optical on-chip position sensing of suspended micro-structures. Microelectromechanical systems dominate the world in sensing technology; they are common in smartphone, automotive, aerospace, and military applications. However, this multibillion dollar industry has failed to make ch ....Towards a unified technology platform for sensing in liquids. Towards a unified technology platform for sensing in liquids. This project aims to use a new sensing platform for hydrocarbon monitoring in water to evolve optical on-chip position sensing of suspended micro-structures. Microelectromechanical systems dominate the world in sensing technology; they are common in smartphone, automotive, aerospace, and military applications. However, this multibillion dollar industry has failed to make chem/bio sensing profitable, mostly due to the absence of a robust and compact read-out technology for sensing in liquids. This project is expected to lead to a unified parallel sensing platform of ultimate sensitivity delivering aqueous sensing for wide ranging applications and markets.Read moreRead less
On-chip spectroscopy and hyperspectral imaging for remote environments. On-chip spectroscopy and hyperspectral imaging for remote environments. This project aims to investigate techniques and materials for building optical spectrometers based on micromachines, usable in portable ground-based and drone-mounted applications in remote environments. Optical spectroscopy is now an accepted technique for materials detection and analysis. The advent of low-cost drone aircraft makes the potential applic ....On-chip spectroscopy and hyperspectral imaging for remote environments. On-chip spectroscopy and hyperspectral imaging for remote environments. This project aims to investigate techniques and materials for building optical spectrometers based on micromachines, usable in portable ground-based and drone-mounted applications in remote environments. Optical spectroscopy is now an accepted technique for materials detection and analysis. The advent of low-cost drone aircraft makes the potential applications of spectroscopy in an imaging form immense. The project expects the resulting low-cost and highly portable technology will transform Australian industry, including securing Australia’s food supply by improving farming practices, aiding mineral exploration, and enhancing capabilities for monitoring Australia’s coastline.Read moreRead less
An investigation of novel Microelectromechanical Systems based technologies for visible/near infra-red spectroscopic imaging. This project will develop new spectroscopic imaging technologies that make possible low-cost, portable instruments with enhanced performance, and that enable new applications. Examples include on-farm precision agriculture, skin cancer detection, food security and processing, airport security, pollution monitoring and industrial process control.