Flowable composite system with short S-glass fibre and halloysite nanotubes. Flowable composite system with short S-glass fibre and halloysite nanotubes. This project aims to design dental materials with reduced amalgams, using a strong but flowable composite with randomly distributed short S-glass fibres and a non-toxic natural nano-composite overlay. This alternative dental composite material is expected to meet international regulatory bodies’ intention to reduce amalgams. Using advanced phot ....Flowable composite system with short S-glass fibre and halloysite nanotubes. Flowable composite system with short S-glass fibre and halloysite nanotubes. This project aims to design dental materials with reduced amalgams, using a strong but flowable composite with randomly distributed short S-glass fibres and a non-toxic natural nano-composite overlay. This alternative dental composite material is expected to meet international regulatory bodies’ intention to reduce amalgams. Using advanced photonic and micro-mechanical techniques to make engineered material is also expected to enhance Australian manufacturing.Read moreRead less
Ytterbium fibre laser with diamond: new laser threshold magnetometry method. This project aims to create a novel class of hybrid optical fibres that open new vistas for magnetic field detection at ambient temperatures in noisy environments. The multidisciplinary project will develop the first fibre laser threshold magnetometry platform that breaks through diamond magnetometry sensitivity limits by cross-cutting established fibre laser technology with the new diamond-glass fibres and magnetometry ....Ytterbium fibre laser with diamond: new laser threshold magnetometry method. This project aims to create a novel class of hybrid optical fibres that open new vistas for magnetic field detection at ambient temperatures in noisy environments. The multidisciplinary project will develop the first fibre laser threshold magnetometry platform that breaks through diamond magnetometry sensitivity limits by cross-cutting established fibre laser technology with the new diamond-glass fibres and magnetometry concepts recently invented by the investigators. Envisaged significant benefits include non-invasive detection of magnetic fields in hard-to-access regions, an area of key interest for remote detection of submarines, early sensing of aircraft corrosion, deep brain imaging of neuronal activities and mineral exploration.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100092
Funder
Australian Research Council
Funding Amount
$270,000.00
Summary
A co-thermal evaporation system for the production of chalcogenide thin films for photonics. This project will provide important infrastructure underpinning the production of novel photonic materials that will allow the fabrication of devices that will support advances in the optical internet; in sensing of dangerous or illicit materials; in defense science and in astro-physics. The production of high performance photonic materials for such applications can lead to new commercial ventures in Aus ....A co-thermal evaporation system for the production of chalcogenide thin films for photonics. This project will provide important infrastructure underpinning the production of novel photonic materials that will allow the fabrication of devices that will support advances in the optical internet; in sensing of dangerous or illicit materials; in defense science and in astro-physics. The production of high performance photonic materials for such applications can lead to new commercial ventures in Australia. Read moreRead less
Engineering Novel Two-dimensional Materials for Optoelectronic Applications. Based on recent breakthroughs in graphene optoelectronics, this project aims to engineer novel two-dimensional nanomaterials and demonstrate new approaches to fabricate optoelectronic devices with potential for light detection and solar light harvesting. The conversion from light signals to electric signals is the central topic in modern telecommunication and solar energy harvesting. By engineering the thinnest material ....Engineering Novel Two-dimensional Materials for Optoelectronic Applications. Based on recent breakthroughs in graphene optoelectronics, this project aims to engineer novel two-dimensional nanomaterials and demonstrate new approaches to fabricate optoelectronic devices with potential for light detection and solar light harvesting. The conversion from light signals to electric signals is the central topic in modern telecommunication and solar energy harvesting. By engineering the thinnest materials in the world, this project aims to develop high value-added devices with high power conversion efficiency for electronic and energy industries. Successful outcomes would enable exciting innovations in the related technology area.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100237
Funder
Australian Research Council
Funding Amount
$389,865.00
Summary
Development of new chemically stable boron nitride-protected phosphor nanocomposites for white light-emitting diodes. White light-emitting diodes (LEDs) are considered the key to next-generation solid-sate lighting. However, further advancements and the large-scale application of white LED innovation has been restricted by the efficiency of current red-emitting phosphors. Although alkaline earth sulphide (AES) red phosphor is a promising candidate for white LEDs, the low chemical stability of AE ....Development of new chemically stable boron nitride-protected phosphor nanocomposites for white light-emitting diodes. White light-emitting diodes (LEDs) are considered the key to next-generation solid-sate lighting. However, further advancements and the large-scale application of white LED innovation has been restricted by the efficiency of current red-emitting phosphors. Although alkaline earth sulphide (AES) red phosphor is a promising candidate for white LEDs, the low chemical stability of AES hinders its utilisation. This project aims to develop new chemically stable boron nitride-protected AES phosphor nanocomposites for white LEDs. The expected outcomes will provide an effective strategy to overcome current phosphor stability problems, and will meet the urgent demand for superior red-emitting phosphors for white LED applications.Read moreRead less
Smart design technology enabling the mid-infrared revolution. While mid-infrared (MIR) lasers have become indispensable to key industries ranging from research and healthcare to defence, industrial deployment of this technology has been hampered by the lack of cost-effective MIR optical fibres. This project aims to overcome this barrier through the creation of an innovative design toolkit for the fabrication of complex optical fibre structures. This efficient and commercially viable concept-to-m ....Smart design technology enabling the mid-infrared revolution. While mid-infrared (MIR) lasers have become indispensable to key industries ranging from research and healthcare to defence, industrial deployment of this technology has been hampered by the lack of cost-effective MIR optical fibres. This project aims to overcome this barrier through the creation of an innovative design toolkit for the fabrication of complex optical fibre structures. This efficient and commercially viable concept-to-manufacture development process will pave the way towards the MIR fibre technology revolution and will yield significant economic benefits spanning industrial process controls and environmental monitoring to hazardous chemical detection and biological sensing.Read moreRead less
Quest for zero optical loss. This project seeks to understand and extend the performance of materials to be used in advanced optical devices based on plasmonic principles. It will lead to the development of new material combinations and alloys that will result in more efficient and sustainable operation.
Nanocrystals in glass: a new nanophotonic material. The new nanophotonic materials will enable breakthroughs in exploitation of the outstanding properties of nanocrystals in photonic devices. This will open up progress in telecommunication, medicine and solar cell technology.
Understanding and optimising the microstructure of Germanium-Arsenic-Selenium glasses for superior device performance. The project will seek to use a combined theoretical and experimental approach to develop 'state of the art' optical glass materials for use in integrated nonlinear optical components. Such materials could be used as optical waveguides in broadband communication systems and offer the possibility of significant improvement in telecommunication performance.