Discovery Early Career Researcher Award - Grant ID: DE240100179
Funder
Australian Research Council
Funding Amount
$461,000.00
Summary
Lead-free Perovskite Nanowires for Artificial Photo-synapse Arrays. This project aims to develop lead-free perovskite nanowires based nanoscale artificial photo-synapse arrays for energy-efficient and high-speed neuromorphic computing applications. The aim will be achieved through engineering the materials interfaces between the perovskite nanowires/electrodes and developing a novel orthogonal electron beam lithography process established by the candidate. The innovative nanoscale integration of ....Lead-free Perovskite Nanowires for Artificial Photo-synapse Arrays. This project aims to develop lead-free perovskite nanowires based nanoscale artificial photo-synapse arrays for energy-efficient and high-speed neuromorphic computing applications. The aim will be achieved through engineering the materials interfaces between the perovskite nanowires/electrodes and developing a novel orthogonal electron beam lithography process established by the candidate. The innovative nanoscale integration of perovskite photo-synapse circuits will be demonstrated for image recognition applications. The success of this project will advance perovskites in the next-generation memristor devices and ensure Australia as a global leader in the emerging technology of perovskite nanoelectronics for neuromorphic computations.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100519
Funder
Australian Research Council
Funding Amount
$420,287.00
Summary
Solving key issues in wearable thermoelectrics for practical applications. Wearable thermoelectrics can directly harvest electricity from body heat, offering a new technology to charge wearable electronics sustainably, but their unsatisfied performance and durability limit their applications. This project aims to design efficient and durable wearable thermoelectrics based on novel carbon/polymer/semiconductor (CPS) hybrid films. The key breakthrough is to develop advanced hybrid materials and de ....Solving key issues in wearable thermoelectrics for practical applications. Wearable thermoelectrics can directly harvest electricity from body heat, offering a new technology to charge wearable electronics sustainably, but their unsatisfied performance and durability limit their applications. This project aims to design efficient and durable wearable thermoelectrics based on novel carbon/polymer/semiconductor (CPS) hybrid films. The key breakthrough is to develop advanced hybrid materials and devices with record-high thermoelectric performance, high stability, and high durability to tackle long-lasting practical application issues. The expected outcomes will lead to innovative technology for energy conversion and advanced manufacturing and place Australia at the forefront of energy and manufacturing.Read moreRead less
New-generation flexible thermoelectrics for wearable electronics. This project aims to develop lightweight, flexible, and durable thermoelectric thin films for wearable electronics using a computation-guided approach, coupled with novel device design and materials nanoengineering strategies. The key breakthrough will overcome the stereotype of fragile thermoelectric materials and their low thermoelectric efficiency for achieving localised, instant, and controllable power generation and/or coolin ....New-generation flexible thermoelectrics for wearable electronics. This project aims to develop lightweight, flexible, and durable thermoelectric thin films for wearable electronics using a computation-guided approach, coupled with novel device design and materials nanoengineering strategies. The key breakthrough will overcome the stereotype of fragile thermoelectric materials and their low thermoelectric efficiency for achieving localised, instant, and controllable power generation and/or cooling with record-high performance in carefully designed wearable thermoelectric devices. Expected outcomes include new understanding of thermoelectrics and innovative technologies for achieving electronics/energy applications, which will provide significant economic and educational benefits for Australia.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
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
Mid-Career Industry Fellowships - Grant ID: IM230100079
Funder
Australian Research Council
Funding Amount
$1,019,275.00
Summary
Bio-inspired Sustainable Materials for Self-powered Environmental Sensing . This project aims to address the industry need for self-powered, light-weight and durable Internet of Things (IoT) devices for environmental sensing applications. The goal will be achieved by designing high power moisture-driven electric generators with a bi-layer interfacial architecture, developing non-flammable energy storage devices with cost-effective electrodes, and printing low power environmental sensors with he ....Bio-inspired Sustainable Materials for Self-powered Environmental Sensing . This project aims to address the industry need for self-powered, light-weight and durable Internet of Things (IoT) devices for environmental sensing applications. The goal will be achieved by designing high power moisture-driven electric generators with a bi-layer interfacial architecture, developing non-flammable energy storage devices with cost-effective electrodes, and printing low power environmental sensors with hetero-structured materials. The key outcome will be a new class of IoT devices with high power density, sustainable output, and real time environmental monitoring capabilities, that will directly benefit Australian industry by providing cost-effective, yet efficient ways to monitor and support safe working environments.Read moreRead less
2D Multiferroics: From Materials Design to Device Conceptualization. This project aims to design new transistors with high efficiency and low energy costing for the storage applications based on two-dimensional multifunctional heterostructures. Extensive computational simulations and joint experiments will be employed to develop fundamental knowledge essential to understanding the phenomena of magnetoelectric coupling, which is used to guide rational device design and implementation. The designe ....2D Multiferroics: From Materials Design to Device Conceptualization. This project aims to design new transistors with high efficiency and low energy costing for the storage applications based on two-dimensional multifunctional heterostructures. Extensive computational simulations and joint experiments will be employed to develop fundamental knowledge essential to understanding the phenomena of magnetoelectric coupling, which is used to guide rational device design and implementation. The designed magnetoelectric heterostructures and the multiferroic devices are expected to provide strong foundations for technological innovations resulting in devices with superior functionality and efficiency. The outcome of the project will significantly benefit high-tech electronics.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100092
Funder
Australian Research Council
Funding Amount
$1,100,000.00
Summary
Quantum microscopy facility for ultrasensitive nanoscale magnetic imaging. Investigations of 2D and van der Waals materials, biological samples, energy materials, and quantum devices on the nano- and microscale are revolutionising medicine, communications, information technology, energy production and storage by virtue of new phenomena. The new quantum microscopy facility will enable state-of-the-art capabilities in mapping chemical, magnetic, optical, electronic, and spectral properties, provid ....Quantum microscopy facility for ultrasensitive nanoscale magnetic imaging. Investigations of 2D and van der Waals materials, biological samples, energy materials, and quantum devices on the nano- and microscale are revolutionising medicine, communications, information technology, energy production and storage by virtue of new phenomena. The new quantum microscopy facility will enable state-of-the-art capabilities in mapping chemical, magnetic, optical, electronic, and spectral properties, providing cutting-edge tools that will enable breakthroughs in both existing and future multi-disciplinary projects in photonics, quantum devices, nanomaterials, nanoelectronics, biotechnology, and energy technology as key drivers of the new economy in Australia.Read moreRead less