Discovery Early Career Researcher Award - Grant ID: DE230101105
Funder
Australian Research Council
Funding Amount
$422,318.00
Summary
Developing Polymer Electrolytes for Operational All-Solid-State Batteries. This project aims to advance the development of safe rechargeable all-solid-state batteries (ASSBs) by innovating fluorinated block copolymers as solid-state electrolytes. ASSBs are the most promising power source for emerging energy storage goals, however, low ionic conductivity and poor long-term cycling stability are critical bottlenecks to their successful application. This project seeks to tackle these challenges by ....Developing Polymer Electrolytes for Operational All-Solid-State Batteries. This project aims to advance the development of safe rechargeable all-solid-state batteries (ASSBs) by innovating fluorinated block copolymers as solid-state electrolytes. ASSBs are the most promising power source for emerging energy storage goals, however, low ionic conductivity and poor long-term cycling stability are critical bottlenecks to their successful application. This project seeks to tackle these challenges by fabricating unique ionic conduction channels and stabilising electrode-electrolyte interfaces using fluorinated block copolymer electrolytes. The expected outcomes are new knowledge in polymer electrolytes and advancement in the commercialisation of ASSBs toward more efficient, safe and reliable energy storage technologies.Read moreRead less
Hot carrier cooling mechanisms in nano structures. This project aims to systematically investigate possible mechanisms of hot carrier cooling in nano structures and to identify the most dominant mechanisms. These are important for efficient hot carrier solar cells and thermoelectrics. This project will develop new physics to understand hot carrier dynamics in nano structures. This project is expected to result in photovoltaic systems with a lower balance of system and levelised cost of electrici ....Hot carrier cooling mechanisms in nano structures. This project aims to systematically investigate possible mechanisms of hot carrier cooling in nano structures and to identify the most dominant mechanisms. These are important for efficient hot carrier solar cells and thermoelectrics. This project will develop new physics to understand hot carrier dynamics in nano structures. This project is expected to result in photovoltaic systems with a lower balance of system and levelised cost of electricity compared to conventional technologies. This should boost solar industry, create green jobs and reduce greenhouse gas emissions.Read moreRead less
Soft Plasmene Nanosheets for Stretchable Plasmonic Skins. Conventional plasmonic sensors and devices are rigid, planar, and not stretchable. This project aims to apply plasmene materials developed at Monash's Nanobionics lab to design highly stretchable plasmonic devices (artificial plasmonic skins). Systematic experimental and theoretical studies will be undertaken to understand how the plasmonic skins respond to strains and how they can be used for fabricating novel stretchable devices. Such s ....Soft Plasmene Nanosheets for Stretchable Plasmonic Skins. Conventional plasmonic sensors and devices are rigid, planar, and not stretchable. This project aims to apply plasmene materials developed at Monash's Nanobionics lab to design highly stretchable plasmonic devices (artificial plasmonic skins). Systematic experimental and theoretical studies will be undertaken to understand how the plasmonic skins respond to strains and how they can be used for fabricating novel stretchable devices. Such studies will generate important new knowledge of fabrication, characterisation, and modelling of stretchable plasmene, hence, contributing to further Australian standing in the field of nanotechnology and plasmonics. It may also incubate patentable technologies, bringing potential economic gains.Read moreRead less
Ultrastretchable, Highly Transparent, Wearable Gold Nanowire Generators. Next-generation wearable electronics should be thin, soft and even transparent, enabling applications impossible to achieve with traditional rigid electronics. Such future electronics will require disruptive soft skin-conformal energy devices to power. This project aims to develop a bi-modal gold nanowire percolation strategy to design ultrathin conductors that are electrically conductive, optically transparent and mechanic ....Ultrastretchable, Highly Transparent, Wearable Gold Nanowire Generators. Next-generation wearable electronics should be thin, soft and even transparent, enabling applications impossible to achieve with traditional rigid electronics. Such future electronics will require disruptive soft skin-conformal energy devices to power. This project aims to develop a bi-modal gold nanowire percolation strategy to design ultrathin conductors that are electrically conductive, optically transparent and mechanically stretchable. It expects to generate new knowledge in nanomaterials design and new technologies to fabricate skin-like invisible wearable generators. This should provide significant benefits in advancing Australian standing in the fields of nanotechnology and energy science, and bringing potential economic gains.Read moreRead less
Thermally conductive materials from boron nitride nanosheets. This project aims to produce novel two-dimensional nanomaterials, in the form of functionalised boron nitride nanosheets and investigate their chemical, thermal and mechanical properties. The project expects to design and develop unique boron nitride nanosheets with targeted thermally conductive and electrically insulating properties, to address the critical technological problem of heat management in electronic devices. The resulting ....Thermally conductive materials from boron nitride nanosheets. This project aims to produce novel two-dimensional nanomaterials, in the form of functionalised boron nitride nanosheets and investigate their chemical, thermal and mechanical properties. The project expects to design and develop unique boron nitride nanosheets with targeted thermally conductive and electrically insulating properties, to address the critical technological problem of heat management in electronic devices. The resulting new nanoscience and ground breaking design and processing techniques will have the capacity to address the current technical obstacles which are preventing further development of fast and smaller electronic devices.Read moreRead less
Biomimetic Design and Fabrication of Smart Dry Adhesives. Gecko footpads have unique structures with amazing features; imitating these fine bio-structures will lead to a multitude of innovations. This project aims to study fundamental principles governing adhesion phenomena for creating entirely new biomimetic nanomaterials with tunable adhesion, self-cleaning and controlled release capabilities. The gecko-mimicking materials and the associated dynamic effects will be characterized quantitativel ....Biomimetic Design and Fabrication of Smart Dry Adhesives. Gecko footpads have unique structures with amazing features; imitating these fine bio-structures will lead to a multitude of innovations. This project aims to study fundamental principles governing adhesion phenomena for creating entirely new biomimetic nanomaterials with tunable adhesion, self-cleaning and controlled release capabilities. The gecko-mimicking materials and the associated dynamic effects will be characterized quantitatively at multiscales and the nanoscale phenomena will be linked to macroscopic performance. The results of this research should provide a fundamental understanding of tunable adhesion mechanisms for the design and development of optimized materials with superb performance of practical significance.
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Quantum Nanostructure Positioning for Breakthrough Quantum Photonics. The integration of quantum nanostructures in optical devices has been proposed to improve the efficiencies of existing optical devices and create new classes of quantum photonics. Limiting progress is that many nanostructures are made through bottom-up processes with inherently randomly distributions, making integration into devices problematic. Lithographic nanostructure fabrication is rarely an option as it leads to diminish ....Quantum Nanostructure Positioning for Breakthrough Quantum Photonics. The integration of quantum nanostructures in optical devices has been proposed to improve the efficiencies of existing optical devices and create new classes of quantum photonics. Limiting progress is that many nanostructures are made through bottom-up processes with inherently randomly distributions, making integration into devices problematic. Lithographic nanostructure fabrication is rarely an option as it leads to diminishes performance. Here, we propose a new and unique nanostructure positioning technique incorporated directly into the growth process. It interfaces bottom-up technologies with device fabrication, facilitating incorporation of nanostructures in photonic devices, and may be transferrable to a variety of other systems.Read moreRead less
Electronics out of thin air: MAGIC - Metal–Air Gated Integrated Circuits. We constantly seek faster, lighter, and energy-efficient devices. This project will create a new class of electronic devices, re-inventing vacuum tubes that enabled electronics almost a century ago, and scaling them down to the nanoscale realm. The devices are termed vacuum channel transistors, and transistors are the critical functional element of all electronics. At the extremely small size scales for nanoelectronics, th ....Electronics out of thin air: MAGIC - Metal–Air Gated Integrated Circuits. We constantly seek faster, lighter, and energy-efficient devices. This project will create a new class of electronic devices, re-inventing vacuum tubes that enabled electronics almost a century ago, and scaling them down to the nanoscale realm. The devices are termed vacuum channel transistors, and transistors are the critical functional element of all electronics. At the extremely small size scales for nanoelectronics, the charge carriers travel very short distances. This avoids collisions enabling extremely high-speed transport. Such a virtual vacuum environment can potentially enable electronics thousands of times faster than the current silicon-based technology, providing a solution to the challenges faced by the semiconductor industry.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100848
Funder
Australian Research Council
Funding Amount
$437,299.00
Summary
Quantum control of sound with light. This project aims to build the first photonic architecture capable of controlling the quantum properties of acoustic waves travelling in crystalline materials and quantum fluids. This level of control is expected to herald new capabilities in sensing applications, quantum information and quantum computing. The project seeks to develop a silicon-based photonic platform that enables the preparation of non-classical states of sound within superfluid helium. This ....Quantum control of sound with light. This project aims to build the first photonic architecture capable of controlling the quantum properties of acoustic waves travelling in crystalline materials and quantum fluids. This level of control is expected to herald new capabilities in sensing applications, quantum information and quantum computing. The project seeks to develop a silicon-based photonic platform that enables the preparation of non-classical states of sound within superfluid helium. This new platform will also be used to develop an ultra-compact silicon-chip based laser. The project outcomes should provide a deeper understanding of quantum fluids and quantum mechanics, and enable the realisation of new quantum technologies with substantial commercialisation potential.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100318
Funder
Australian Research Council
Funding Amount
$368,554.00
Summary
Superfluid optomechanics with quantised vortices. This project aims to develop new technologies to probe and control the flow of superfluid helium at size-scales never before possible. Superfluid helium is the only quantum liquid, characterised by flow without dissipation and quantised vortices. Leveraging the techniques of cavity optomechanics, this project aims to demonstrate control of superfluid helium properties at the quantum level, including the first demonstration of laser-cooling of a l ....Superfluid optomechanics with quantised vortices. This project aims to develop new technologies to probe and control the flow of superfluid helium at size-scales never before possible. Superfluid helium is the only quantum liquid, characterised by flow without dissipation and quantised vortices. Leveraging the techniques of cavity optomechanics, this project aims to demonstrate control of superfluid helium properties at the quantum level, including the first demonstration of laser-cooling of a liquid into its quantum ground-state. The devices developed in this project will also serve as probes of unprecedented sensitivity for the study of 2D superfluid helium. The new technologies developed will have potential for broad uptake in the scientific community and generation of intellectual property and patents for quantum technology and inertial sensors.Read moreRead less