Bioelectronic logic. This project aims to understand ion-electron interactions relevant to bioelectronics, and create transducing interfaces. Bioelectronics is a frontier field which aims to connect biological systems with modern electronics and so create biomedical devices. Transducing ion and electron signals using a biocompatible functional interface is difficult since ion and electron physics are different. By combining individual transducers, this project intends to demonstrate ground-break ....Bioelectronic logic. This project aims to understand ion-electron interactions relevant to bioelectronics, and create transducing interfaces. Bioelectronics is a frontier field which aims to connect biological systems with modern electronics and so create biomedical devices. Transducing ion and electron signals using a biocompatible functional interface is difficult since ion and electron physics are different. By combining individual transducers, this project intends to demonstrate ground-breaking bioelectronic logic capable of interface-level processing. The stretch goal is to test this new logic with a biological neuronal model. The project could deliver new science and interfacing elements to integrate tissue and circuitry, and demonstrate these in a real biological model.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100158
Funder
Australian Research Council
Funding Amount
$470,000.00
Summary
Small angle X-ray scattering facility for Queensland. This project aims to provide an advanced small angle X-ray scattering facility for the examination of versatile porous and nano-size sample types. Understanding the structure-function relationship is crucial for developing high-performance nanostructured materials in bio-applications, renewable energy, energy storage, and water treatment. The proposed facility will support the development of new functional materials for industry reform, mappi ....Small angle X-ray scattering facility for Queensland. This project aims to provide an advanced small angle X-ray scattering facility for the examination of versatile porous and nano-size sample types. Understanding the structure-function relationship is crucial for developing high-performance nanostructured materials in bio-applications, renewable energy, energy storage, and water treatment. The proposed facility will support the development of new functional materials for industry reform, mapping oil and gas reserves, developing innovative technologies for new energy resources, and gas deliverability. The project is strongly aligned with the Advanced Manufacturing Science and Research Priority by providing high-performance materials, and generating new technologies to support major industries in Queensland and Australia.Read moreRead less
Molecular Alignments in Organic Semiconductors. The proposed research project is focus on molecular alignments in solution-based organic semiconductors, which is at the frontier of research in the interdisciplinary field of plastic electronics. Molecular ordering has tremendous potential in enhancing both electrical and optical properties and opens up a way to realise new class of molecular electronic and optoelectronic devices. Significant learning from these devices can be applied to practical ....Molecular Alignments in Organic Semiconductors. The proposed research project is focus on molecular alignments in solution-based organic semiconductors, which is at the frontier of research in the interdisciplinary field of plastic electronics. Molecular ordering has tremendous potential in enhancing both electrical and optical properties and opens up a way to realise new class of molecular electronic and optoelectronic devices. Significant learning from these devices can be applied to practical high performance devices to be extremely cheap, recyclable, and mechanical flexible. Read moreRead less
Light Emitting Transistors: A New Route to Digital Displays and Lasers. This project intends to create new light-emitting display technology with the potential to offer much cheaper, recyclable, and mechanically flexible semiconductors. Organic light-emitting field effect transistors are an emerging class of integrated optoelectronic device with dual functionalities (ie a light emitting and a switch transistor in single device structure). The dual-functioned devices provide a promising pathway t ....Light Emitting Transistors: A New Route to Digital Displays and Lasers. This project intends to create new light-emitting display technology with the potential to offer much cheaper, recyclable, and mechanically flexible semiconductors. Organic light-emitting field effect transistors are an emerging class of integrated optoelectronic device with dual functionalities (ie a light emitting and a switch transistor in single device structure). The dual-functioned devices provide a promising pathway to much more economical display technologies and tunable organic lasers. The principal goal of this project is to develop a new route to achieve simplified display pixels and electrically pumped organic lasers by using organic light-emitting transistors platform with new organic chromophores. The new semiconductors could be easily integrated into a wide range of applications such as telecommunications, biomedical and consumer electronics.Read moreRead less
Organic-inorganic hybrid electronic devices and logic circuits. This project will create the next generation of opto-electronic devices and logic circuits using solution-based organic-inorganic hybrid materials with the potential to be extremely cheap, recyclable, and mechanically flexible. This project aims to position Australia as a leader in printed electronics.
Organic superconductors and frustrated antiferromagnets: from quantum chemistry to quantum many-body theory to experiment. Aims. To obtain an understanding of how quantum physics and the
interactions between electrons determine the unusual properties of
organic superconductors and frustrated antiferromagnets.
Significance. The project brings together investigators who are
each world leaders in their respective areas of expertise.
Expected outcomes. Answers will be obtained to fundamenta ....Organic superconductors and frustrated antiferromagnets: from quantum chemistry to quantum many-body theory to experiment. Aims. To obtain an understanding of how quantum physics and the
interactions between electrons determine the unusual properties of
organic superconductors and frustrated antiferromagnets.
Significance. The project brings together investigators who are
each world leaders in their respective areas of expertise.
Expected outcomes. Answers will be obtained to fundamental questions about how the quantum
properties of individual molecules combine to determine the
macroscopic properties of new states of matter.Read moreRead less
Interplay of superconductivity and magnetism in layered molecular crystals. The most interesting new electronic materials discovered in the past decade are built from layers of atoms or molecules. Many exhibit a subtle competition between magnetism and superconductivity.
This project will develop new theoretical concepts and models for the electronic properties of organic molecular crystals. The theoretical predictions will be tested experimentally at the USA National High Magnetic Field Labo ....Interplay of superconductivity and magnetism in layered molecular crystals. The most interesting new electronic materials discovered in the past decade are built from layers of atoms or molecules. Many exhibit a subtle competition between magnetism and superconductivity.
This project will develop new theoretical concepts and models for the electronic properties of organic molecular crystals. The theoretical predictions will be tested experimentally at the USA National High Magnetic Field Laboratory.
The outcome will be a better understanding of a wide range of materials (including high-temperature superconductors, giant magnetoresistance and plastic electronic materials) that could be the
basis of much of the electronic technology of the twenty-first century.Read moreRead less
A portable sensor for explosives. The National Research priority, safeguarding Australia, recognises that there is a real threat of terrorism and the need to protect Australians at home and abroad. Although there is often talk of dirty bombs, and biological and nuclear terrorism, the most easily sourced weapon of the terrorist is still the conventional explosive. The ability to detect trace amounts of explosives is therefore required. This means that there is a real need for a portable detection ....A portable sensor for explosives. The National Research priority, safeguarding Australia, recognises that there is a real threat of terrorism and the need to protect Australians at home and abroad. Although there is often talk of dirty bombs, and biological and nuclear terrorism, the most easily sourced weapon of the terrorist is still the conventional explosive. The ability to detect trace amounts of explosives is therefore required. This means that there is a real need for a portable detection system with the ability to reliably sense a specific explosive selectively at low concentrations. This project concerns the development of a new handheld sensor that has the potential to increase the nation's security.Read moreRead less
Biocompatible Electro-Ionic Signal Transduction. Bioelectronics is a new frontier field concerned with integrating electrical control systems and biological entities for applications such as in-situ bio-monitoring and cellular-level control and interrogation of tissue. Electrical signals in biology are mostly carried by ion currents, whilst conventional electronics rely on electrons. This project addresses the critical challenge of bioelectronics; the development of biocompatible electrical inte ....Biocompatible Electro-Ionic Signal Transduction. Bioelectronics is a new frontier field concerned with integrating electrical control systems and biological entities for applications such as in-situ bio-monitoring and cellular-level control and interrogation of tissue. Electrical signals in biology are mostly carried by ion currents, whilst conventional electronics rely on electrons. This project addresses the critical challenge of bioelectronics; the development of biocompatible electrical interfaces capable of transducing ion-and-electron currents. This project will specifically study the complex transport physics of conducting biomacromolecules and develop new interface devices, with an ultimate goal is to create a simple and generic transducing element for cellular-level electrical communication. Read moreRead less
Surface and Interface Engineering for Superconducting Quantum Circuits. The limiting factor for current quantum computers is a process called decoherence. This project aims to identify new strategies to reduce decoherence in quantum computer components using an interdisciplinary approach based on quantum physics, materials science, and engineering. This project involves investigating the effect of
atomically sharp interfaces on decoherence and using capping layers to control and/or inhibit oxide ....Surface and Interface Engineering for Superconducting Quantum Circuits. The limiting factor for current quantum computers is a process called decoherence. This project aims to identify new strategies to reduce decoherence in quantum computer components using an interdisciplinary approach based on quantum physics, materials science, and engineering. This project involves investigating the effect of
atomically sharp interfaces on decoherence and using capping layers to control and/or inhibit oxide growth that reduce the contribution of interfaces to decoherence. Expected outcomes of this project include development of solutions to fabricate long-lived superconducting qubits benefiting superconducting quantum technologies and making a significant step towards realisation of a practical quantum computer.Read moreRead less