How beetles harness near-infrared properties to enhance energy efficiency. This project aims to discover how animals use nanophotonic structures to manipulate near infra-red light for thermal control and visual information. Almost nothing is currently known about the mechanism, function and evolution of near-infrared properties in animals, despite their potential importance for maintaining body temperatures within the critical thermal limits for survival. The project uses multidisciplinary techn ....How beetles harness near-infrared properties to enhance energy efficiency. This project aims to discover how animals use nanophotonic structures to manipulate near infra-red light for thermal control and visual information. Almost nothing is currently known about the mechanism, function and evolution of near-infrared properties in animals, despite their potential importance for maintaining body temperatures within the critical thermal limits for survival. The project uses multidisciplinary techniques from optical physics, physiology and evolutionary biology to reveal near-infrared adaptations in socially and economically important Christmas beetles. The intended outcomes include a bio-informed blueprint for a new class of functional nanomaterials that enhance energy efficiency.Read moreRead less
Numerical simulation of the fish-like swimming of linked bodies. Although Zoologists have made detailed observations of swimming fish there are still many unanswered questions about how they swim. We do not know how the fins and undulating body work together to produce the high speed of the tuna, or the fast turns of a fish escaping danger. We see dolphins swim through the sea's surface but we don't know if they do that because it is much more efficient. This project is designed to simulate arb ....Numerical simulation of the fish-like swimming of linked bodies. Although Zoologists have made detailed observations of swimming fish there are still many unanswered questions about how they swim. We do not know how the fins and undulating body work together to produce the high speed of the tuna, or the fast turns of a fish escaping danger. We see dolphins swim through the sea's surface but we don't know if they do that because it is much more efficient. This project is designed to simulate arbitrary fish motion and give answers to these and other questions concerning swimming. It may also help humans to swim more efficiently and provide simulation tools for the design of robotic undersea vehicles.Read moreRead less
Discovering nature's photonic devices to control light and heat. This project aims to discover how and why beetles and butterflies reflect near-infrared light. Reflection of near-infrared radiation may be critical to prevent overheating, yet its role in thermal protection remains largely unexplored. The project will integrate evolutionary biology, optical physics and biophysics to reveal the diversity, mechanism, function and evolution of near-infrared signatures. Expected outcomes include the d ....Discovering nature's photonic devices to control light and heat. This project aims to discover how and why beetles and butterflies reflect near-infrared light. Reflection of near-infrared radiation may be critical to prevent overheating, yet its role in thermal protection remains largely unexplored. The project will integrate evolutionary biology, optical physics and biophysics to reveal the diversity, mechanism, function and evolution of near-infrared signatures. Expected outcomes include the discovery of nature’s solutions to selection for both optical (camouflage, communication) and thermal functions. The project will have significant benefits such as creating opportunities to develop biomimetic and bioinspired materials to enhance energy efficiency, which will have significant economic and environmental benefits.Read moreRead less
Nature’s advanced optical materials and their role in thermal management. This project aims to discover the nano-structural properties of beetles than enable effective management of solar and thermal radiation in different environments. A further aim is to reveal how these composite biological materials combine thermal control with desirable mechanical properties, such as strength and flexibility. Passive control of radiative energy is critical for both animal survival and for the design of many ....Nature’s advanced optical materials and their role in thermal management. This project aims to discover the nano-structural properties of beetles than enable effective management of solar and thermal radiation in different environments. A further aim is to reveal how these composite biological materials combine thermal control with desirable mechanical properties, such as strength and flexibility. Passive control of radiative energy is critical for both animal survival and for the design of many manufactured materials, particularly in a warming world. This interdisciplinary project will provide new knowledge of the different ways that biological materials mediate radiative energy exchange with the environment. This knowledge is essential for the design of bioinspired, energy-efficient, multi-functional materials.Read moreRead less
Quantum effects in photosynthesis: responsible for highly efficient energy transfer or trivial coincidence? Understanding the precise details of the highly efficient energy transfer processes in photosynthesis has the potential to impact the design of efficient solar energy solutions. This project will gain this understanding by exploring the nature of interactions between different components and the significance of quantum mechanics.
A New Window on Photosynthesis: Ultrafast Coherence Dynamics in Biomolecules and Semiconductor Nanostructures. Recent research has indicated that the remarkable efficiency of energy capture and transfer in photosynthesis may be due to the effects of quantum coherence, which is an intrinsically non-classical phenomenon. We will investigate these effects in biological and nanofabricated systems using ultrafast laser spectroscopy . An understanding of these energy transfer processes may open the d ....A New Window on Photosynthesis: Ultrafast Coherence Dynamics in Biomolecules and Semiconductor Nanostructures. Recent research has indicated that the remarkable efficiency of energy capture and transfer in photosynthesis may be due to the effects of quantum coherence, which is an intrinsically non-classical phenomenon. We will investigate these effects in biological and nanofabricated systems using ultrafast laser spectroscopy . An understanding of these energy transfer processes may open the door to the development to a range of new technologies, including clean and virtually limitless energy sources that convert solar energy directly into useful power and quantum computers that will revolutionize our ability to process information.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347356
Funder
Australian Research Council
Funding Amount
$238,000.00
Summary
Real-time multi-dimensional multi-photon microscopy facility. The proposal seeks to establish an integrated microscopy facility and thus to expand the high-resolution imaging capabilities at Swinburne University of Technology, Peter MacCallum Cancer Institute and the University of Melbourne. The provision of the equipment requested will establish an innovative real-time multi-dimensional multi-photon imaging facility of world class. This facility will be accessed on a cooperative basis by the pa ....Real-time multi-dimensional multi-photon microscopy facility. The proposal seeks to establish an integrated microscopy facility and thus to expand the high-resolution imaging capabilities at Swinburne University of Technology, Peter MacCallum Cancer Institute and the University of Melbourne. The provision of the equipment requested will establish an innovative real-time multi-dimensional multi-photon imaging facility of world class. This facility will be accessed on a cooperative basis by the participants and will be available for collaborative projects with other Australian institutions and industry. The requested equipment will be used in conjunction with existing femtosecond laser and lifetime imaging systems installed in the research laboratories of the participating institutions. The facility will enable real-time investigations of biomolecular processes and the development of novel biomedical imaging techniques as well as the state-of-the-art nanophotonic devices such as nano-tweezers and nano compact disks.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100114
Funder
Australian Research Council
Funding Amount
$420,000.00
Summary
Multi-scale imaging and characterisation facility for biological structure and function. Discovery in biology will lead to significant social and economic impact improving Australians' lives. This facility will allow researchers to study the micro and nanoscales structure and function of cells, tissues and organs. The knowledge gained will have direct benefits and applications to human and animal health, drug and food technology.
Paving the way for ultra-long haul flights: strategies to mitigate jetlag. This project aims to develop and test strategies to mitigate jetlag, founded on biophysical modelling of circadian rhythms. It sets out to quantify the speed of circadian adaptation of sleep, alertness, and metabolism after transmeridian travel and to maximise speed of adaptation via optimised timing of light exposure, food, and exercise in-flight and on-the-ground. Expected outcomes include powerful models for jetlag str ....Paving the way for ultra-long haul flights: strategies to mitigate jetlag. This project aims to develop and test strategies to mitigate jetlag, founded on biophysical modelling of circadian rhythms. It sets out to quantify the speed of circadian adaptation of sleep, alertness, and metabolism after transmeridian travel and to maximise speed of adaptation via optimised timing of light exposure, food, and exercise in-flight and on-the-ground. Expected outcomes include powerful models for jetlag strategies, ready for application in air travel. The project will directly inform Qantas’ operations for ultra-long haul flights and their international network more broadly. Project outcomes will benefit society and the economy through improving travellers’ alertness, sleep, and reducing the risk of fatigue-related accidents.Read moreRead less