Nanoengineered hybrid coatings that control inflammation to artificial bone. This project aims to develop novel biocompatible surfaces using nanotechnology approaches to understand how cells attach to and grow on artificial bone materials. This research is significant because it combines novel nanofabrication and surface modification strategies for unprecedented control and manipulation of inflammatory cell behaviour relevant to orthopaedic implants. The project will overcome current limitations ....Nanoengineered hybrid coatings that control inflammation to artificial bone. This project aims to develop novel biocompatible surfaces using nanotechnology approaches to understand how cells attach to and grow on artificial bone materials. This research is significant because it combines novel nanofabrication and surface modification strategies for unprecedented control and manipulation of inflammatory cell behaviour relevant to orthopaedic implants. The project will overcome current limitations of uncontrollable inflammatory reactions to surfaces. The multifunctional surfaces are expected to give the biomaterials field new tools to control and maintain bone cell functionality, in vitro. Potential long-term benefits include applications as coatings in tissue engineering, regenerative medicine, and medical implants.Read moreRead less
Zwitterion-based electrolytes for advanced energy technologies. This research aims to develop a new class of electrolyte that is safer, non-flammable and designed to enable excellent performance of high energy batteries made with either sodium or lithium. Through the synthesis of new electrolyte structures that are designed to improve stability and electrochemical properties, and using a range of analysis techniques to understand the material properties, the project aims to solve some of the saf ....Zwitterion-based electrolytes for advanced energy technologies. This research aims to develop a new class of electrolyte that is safer, non-flammable and designed to enable excellent performance of high energy batteries made with either sodium or lithium. Through the synthesis of new electrolyte structures that are designed to improve stability and electrochemical properties, and using a range of analysis techniques to understand the material properties, the project aims to solve some of the safety and performance problems that plague existing electrolytes. Expected benefits include new functional energy materials for safer, more reliable energy storage technologies, plus research training, collaborations and materials development capabilities to help position Australia as a global leader in this field.Read moreRead less
Enabling High-performance Layered Oxide Sodium-Ion Battery Cathodes. The great abundance of sodium on the earth's crust and similar work principles have made sodium-ion batteries the most promising replacement for commercial lithium-ion batteries, which are struggling with the increasing cost. This project studies the layered oxides for use as cathodes in sodium-ion batteries. The cross-disciplinary strategy and approaches will be employed to address the weaknesses of such oxides and release the ....Enabling High-performance Layered Oxide Sodium-Ion Battery Cathodes. The great abundance of sodium on the earth's crust and similar work principles have made sodium-ion batteries the most promising replacement for commercial lithium-ion batteries, which are struggling with the increasing cost. This project studies the layered oxides for use as cathodes in sodium-ion batteries. The cross-disciplinary strategy and approaches will be employed to address the weaknesses of such oxides and release the hidden potential to achieve commercialisation. The expected outcome includes advancement in fundamental knowledge of cathode materials design and the development of clean energy, revamping the energy structure of Australia. Read moreRead less
Mixed-Dimensional 2D/0D Heterostructures for Infrared Detection. The aim of this proposal is to develop novel mixed-dimensional 2D/0D heterostructures based on halide and chalcogenide nanomaterials to construct a highly efficient solution-processing platform for short wave infrared detection. Moreover, innovative low-dose transmission electron microscopy and spectroscopy will be applied to unveil the fundamental structure-property relationship and fill the gap of knowledge for these materials. S ....Mixed-Dimensional 2D/0D Heterostructures for Infrared Detection. The aim of this proposal is to develop novel mixed-dimensional 2D/0D heterostructures based on halide and chalcogenide nanomaterials to construct a highly efficient solution-processing platform for short wave infrared detection. Moreover, innovative low-dose transmission electron microscopy and spectroscopy will be applied to unveil the fundamental structure-property relationship and fill the gap of knowledge for these materials. Such mixed-dimensional nano-heterostructures combining 2D halide perovskites with 0D quantum dots with complementary physical properties and atomically resolved interfaces will significantly enhance the performance, thereby enabling breakthroughs in a broad range of disruptive optoelectronic technologies. Read moreRead less
Diamane: A New Frontier in Materials Science. Single-layer diamond (‘diamane’) is a new frontier of material research although its preparation is still in infancy with many structures predicted possible but have not been made experimentally. Built on a new chemical route for 'graphite to diamane' transformation, this project will address a research gap towards synthesising new diamane(-like) nanostructures and developing an in-depth understanding of the chemically induced phase transformation an ....Diamane: A New Frontier in Materials Science. Single-layer diamond (‘diamane’) is a new frontier of material research although its preparation is still in infancy with many structures predicted possible but have not been made experimentally. Built on a new chemical route for 'graphite to diamane' transformation, this project will address a research gap towards synthesising new diamane(-like) nanostructures and developing an in-depth understanding of the chemically induced phase transformation and structure-property correlations, which will have far-reaching impact on scientific fields beyond carbon research. Preliminary data points to both feasibility and impact for discovering new materials and technologies, which will bring foreseeable scholarly, economic, and social benefits.Read moreRead less
Physics-based equivalent circuit models for nanoporous electrodes. This project aims to develop new physics-based equivalent circuit models for ion/electron coupled dynamics in electrified porous nanomaterials via fusing latest simulation advances with machine learning approach. This project expects to meet the challenge of high-efficient and accurate dynamic models for accelerated design, accurate diagnosis, and optimal operation of electrochemical energy storage and conversion technologies. Th ....Physics-based equivalent circuit models for nanoporous electrodes. This project aims to develop new physics-based equivalent circuit models for ion/electron coupled dynamics in electrified porous nanomaterials via fusing latest simulation advances with machine learning approach. This project expects to meet the challenge of high-efficient and accurate dynamic models for accelerated design, accurate diagnosis, and optimal operation of electrochemical energy storage and conversion technologies. The outcome will be a paradigm shift of how equivalent circuit models are developed and used, informed by new scientific knowledge and data. The proliferation of the new models will allow design and operation of more efficient and durable technologies in energy industry, benefitting Australian economy and environment.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100036
Funder
Australian Research Council
Funding Amount
$754,700.00
Summary
Ultra-fast structure-property characterisation of materials. The design of materials for functional and damage-tolerant applications requires detailed knowledge of their structure and the mechanisms that operate at length scales ranging from interatomic layers to micro, meso and macro scales. This project aims to establish ultra-fast processing capabilities that enable ion-damage free structural modifications and microstructure-mechanical properties characterisation across multiple length scales ....Ultra-fast structure-property characterisation of materials. The design of materials for functional and damage-tolerant applications requires detailed knowledge of their structure and the mechanisms that operate at length scales ranging from interatomic layers to micro, meso and macro scales. This project aims to establish ultra-fast processing capabilities that enable ion-damage free structural modifications and microstructure-mechanical properties characterisation across multiple length scales at unprecedented speed and accuracy. Expected outcomes include the ability to create new knowledge about multi-scale structure, composition and deformation mechanisms for the design of novel materials systems that enable manufacturing benefits throughout transportation, defence and clean energy sectors.Read moreRead less
Engineered topological nanostructures – a new frontier in materials design. The aim of engineering and utilising topological defects such as domain walls and and skyrmions in functional materials is currently receiving tremendous attention. Their significance lies in a plethora of fascinating phenomena for fundamental research and future technological applications in nanoelectronics. One frontier area of research is negative capacitance nanoelectronics using such materials, carrying the prospect ....Engineered topological nanostructures – a new frontier in materials design. The aim of engineering and utilising topological defects such as domain walls and and skyrmions in functional materials is currently receiving tremendous attention. Their significance lies in a plethora of fascinating phenomena for fundamental research and future technological applications in nanoelectronics. One frontier area of research is negative capacitance nanoelectronics using such materials, carrying the prospect of revolutionizing ultralow energy electronics, which will be developed here. The project's expected outcomes are new concepts for the synthesis and design of topological nanostructures for such applications. The utilization of these materials will benefit efficient controllable functionality for future nanoelectronics.Read moreRead less
Engineering Functional Antimicrobial Polypeptide Surfaces. Antimicrobial coatings are vital in preventing bacterial contamination but a versatile solution does not exist. Structurally nanoengineered antimicrobial peptide polymers (SNAPPs) were recently developed to fight multidrug-resistant bacteria. To expand their application into antimicrobial coatings across a range of surfaces, a simple and universal coating strategy is needed. By developing phenolic-functionalised SNAPPs, this project aims ....Engineering Functional Antimicrobial Polypeptide Surfaces. Antimicrobial coatings are vital in preventing bacterial contamination but a versatile solution does not exist. Structurally nanoengineered antimicrobial peptide polymers (SNAPPs) were recently developed to fight multidrug-resistant bacteria. To expand their application into antimicrobial coatings across a range of surfaces, a simple and universal coating strategy is needed. By developing phenolic-functionalised SNAPPs, this project aims to exploit the adhesive nature of metal–phenolic materials to rapidly coat diverse surfaces, including stainless steel and textiles. The expected outcome is the generation of antimicrobial polypeptide surfaces, which will have benefits in food safety, medical implant technology and advanced textiles.Read moreRead less
Programmable Ferroelectric Nanoelectronics for In-memory Computing. The project aims to explore and develop the next-generation ferroelectric memory addressing the energy and speed issues of computers. Modern digital computers are notoriously energy consuming and slow, especially, when performing data-intensive tasks, e.g. identifying images and making decisions. This gap will be bridged by advancing novel ferroelectric quantum memory concepts and prototypes. Expected outcomes include new memory ....Programmable Ferroelectric Nanoelectronics for In-memory Computing. The project aims to explore and develop the next-generation ferroelectric memory addressing the energy and speed issues of computers. Modern digital computers are notoriously energy consuming and slow, especially, when performing data-intensive tasks, e.g. identifying images and making decisions. This gap will be bridged by advancing novel ferroelectric quantum memory concepts and prototypes. Expected outcomes include new memory design, material principles and ferroelectric devices capable of not only storing huge amounts of data but also instant fast processing and brain like learning. Project benefits include high performance hardware solutions for Artificial Intelligence and Big data boosting Australian quantum technology and industries.Read moreRead less