Exploring piezoelectricity of two-dimensional nanocrystals and nanodevices. This project aims to study piezoelectricity in two-dimensional (2D) nanocrystals and nano-devices. This project expects to result in the formulation of new 2D piezoelectric, ferroelectric and multiferroic theory, syntheses of 2D crystals and exploration of their functionalities, which are directly implemented in innovative electronic and photonic components. This will contribute to the advancement of both new 2D multifun ....Exploring piezoelectricity of two-dimensional nanocrystals and nanodevices. This project aims to study piezoelectricity in two-dimensional (2D) nanocrystals and nano-devices. This project expects to result in the formulation of new 2D piezoelectric, ferroelectric and multiferroic theory, syntheses of 2D crystals and exploration of their functionalities, which are directly implemented in innovative electronic and photonic components. This will contribute to the advancement of both new 2D multifunctional materials and new nanodevice structures which may open up unprecedented opportunities for both scientific and technological endeavoursRead moreRead less
Unravelling structure-function relationships in high mobility donor-acceptor co-polymers. This project seeks to understand the high-performance of a new generation of semiconducting plastics. This research will enable the development of low-cost printed electronics such as flexible displays and sensors.
Boolean plasmonics: the design of nano-optical logic gates. The success of this project will see the development of an all-optical nano-scale logic gate. Such a device will drastically improve communications and information technology. Standard lithographic techniques will be used ensuring reproducibility and mass production, placing Australia at the forefront of the photonic market.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100190
Funder
Australian Research Council
Funding Amount
$205,000.00
Summary
High through-put facility for measurement of quantum materials and devices. This projects aims to accelerate the development of quantum technologies by expanding our capacity to rapidly evaluate the low temperature electrical and optical properties of novel materials and devices. The project expects to generate new knowledge in quantum coherent phases of diamond, high mobility two-dimensional spintronics, hybrid semiconductor-superconductor devices, novel phases of silicon and germanium, and sin ....High through-put facility for measurement of quantum materials and devices. This projects aims to accelerate the development of quantum technologies by expanding our capacity to rapidly evaluate the low temperature electrical and optical properties of novel materials and devices. The project expects to generate new knowledge in quantum coherent phases of diamond, high mobility two-dimensional spintronics, hybrid semiconductor-superconductor devices, novel phases of silicon and germanium, and single photon sources based on silicon-carbide. Expected outcomes of the project include the establishment of high performing, efficient, new facilities for low temperature quantum measurement, the strengthening of collaborative links between participating researchers and the expansion of opportunities for research students.Read moreRead less
Surface doping of diamond: A new platform for 2D carbon-based spintronics. This project aims to develop the hydrogen-terminated surface of diamond as a new semiconducting platform for carbon-based spintronics. It will build upon recent experimental advances that have shown diamond to possess a two-dimensional (2D) hole-based system with strong spin-orbit coupling. As a semiconductor with unique spin properties, surface conducting diamond offers considerable advantages over other 2D materials su ....Surface doping of diamond: A new platform for 2D carbon-based spintronics. This project aims to develop the hydrogen-terminated surface of diamond as a new semiconducting platform for carbon-based spintronics. It will build upon recent experimental advances that have shown diamond to possess a two-dimensional (2D) hole-based system with strong spin-orbit coupling. As a semiconductor with unique spin properties, surface conducting diamond offers considerable advantages over other 2D materials such as graphene and topological insulators. These unique properties will be exploited to realise novel semiconductor device architectures for the manipulation of spin using electric fields, and for the study of new spin transport phenomena and quasiparticle excitations at semiconductor-superconductor interfaces.Read moreRead less
Multilayer thin film memristors: designing interfaces and defect states in perovskites for nanoscale multi-state memories. This project will explore memristive devices, a frontier electronic memory technology, where the memory element's behaviour depends on its prior electronic experiences. This project will attempt to understand the processes that govern the storage and recall of information, to realise functional materials and interfaces that maximise memristive performance.
Discovery Early Career Researcher Award - Grant ID: DE160100023
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
Flexible transparent oxides – the future of electronics is clear. This project aims to support the development of flexible electronic devices incorporating the functional properties of oxide thin films. Oxide thin films require high processing temperatures, which are incompatible with flexible substrates. This project seeks to provide a solution by using a novel transfer process that allows oxides to be combined with flexible polymer substrates. Applications in sensing under the influence of hea ....Flexible transparent oxides – the future of electronics is clear. This project aims to support the development of flexible electronic devices incorporating the functional properties of oxide thin films. Oxide thin films require high processing temperatures, which are incompatible with flexible substrates. This project seeks to provide a solution by using a novel transfer process that allows oxides to be combined with flexible polymer substrates. Applications in sensing under the influence of heat, gas, and light will be studied. This project will potentially create devices that can be conformally applied to surfaces or worn on a person to act as low-cost sensors for toxic gases or ultraviolet radiation.Read moreRead less
Bioinspired photoreceptor and smart neural mimicking technologies. The project aims to address fundamental questions regarding bioinspired artificial photoreceptors and neural-mimicking technologies that precisely mimic light capture abilities of photoreceptors, processing of retinal ganglion cells and functionalities in neurons. This is expected to generate new fundamental and applied knowledge in bioengineered optoelectronic systems. Expected outcomes of the project include new materials with ....Bioinspired photoreceptor and smart neural mimicking technologies. The project aims to address fundamental questions regarding bioinspired artificial photoreceptors and neural-mimicking technologies that precisely mimic light capture abilities of photoreceptors, processing of retinal ganglion cells and functionalities in neurons. This is expected to generate new fundamental and applied knowledge in bioengineered optoelectronic systems. Expected outcomes of the project include new materials with tailored properties at an atomic level for dynamic control of current under different light stimulus wavelengths. This should provide significant benefits such as new advanced materials driven smart architectures that overcome limitations of solid-state systems for next generation of smart technologies. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100104
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Collaborative facility for high resolution fabrication, imaging, and characterisation of nanostructured materials. Collaborative facility for high resolution fabrication, imaging, and characterisation of nanostructured materials: The development of the next generation of electronic, optical, and biomedical devices requires methods that can quickly manipulate and characterise matter at the nanoscale. This project will establish new tools that will allow researchers to build novel device structure ....Collaborative facility for high resolution fabrication, imaging, and characterisation of nanostructured materials. Collaborative facility for high resolution fabrication, imaging, and characterisation of nanostructured materials: The development of the next generation of electronic, optical, and biomedical devices requires methods that can quickly manipulate and characterise matter at the nanoscale. This project will establish new tools that will allow researchers to build novel device structures and analyse them at nanoscale spatial resolutions. The new facilities are required to meet the demands of a growing number of innovative projects being undertaken within a large multidisciplinary consortium of research groups. The facilities will be housed in state-of-the art laboratories and managed as open access resources for researchers which will enable advances in the areas of energy harvesting, environmental monitoring, and electronics.Read moreRead less
Scalable atom-thin materials for monolithic electronics & optoelectronics. This project aims to understand large-area growth mechanisms and create practical, controllable doping methodologies for developing manufacturing-compatible tunable materials to overcome technological challenges presented by silicon. The project expects to generate new understanding of physico-chemical mechanisms that govern the optical and electrical properties of an emerging class of materials only few-atoms thick that ....Scalable atom-thin materials for monolithic electronics & optoelectronics. This project aims to understand large-area growth mechanisms and create practical, controllable doping methodologies for developing manufacturing-compatible tunable materials to overcome technological challenges presented by silicon. The project expects to generate new understanding of physico-chemical mechanisms that govern the optical and electrical properties of an emerging class of materials only few-atoms thick that offer unprecedented opportunities. This is expected to establish a suite of atomically-thin materials that will be deployed in miniaturised, high-density electronics and optoelectronics of which proof-of-concept functional devices are proposed to be demonstrated. These will be leveraged to explore industry partnerships.Read moreRead less