Diamond lasers for precision applications. Diamond lasers for precision applications. The project aims to create single mode lasers of ultrahigh spectral brightness. Single-mode lasers could improve many areas of science and technology, but existing technologies do not meet all performance requirements. This project will harness the intrinsic properties of diamond Raman lasers to increase the wavelength reach, power and stability of single mode lasers. The expected outcome is laser technology th ....Diamond lasers for precision applications. Diamond lasers for precision applications. The project aims to create single mode lasers of ultrahigh spectral brightness. Single-mode lasers could improve many areas of science and technology, but existing technologies do not meet all performance requirements. This project will harness the intrinsic properties of diamond Raman lasers to increase the wavelength reach, power and stability of single mode lasers. The expected outcome is laser technology that satisfies the needs of emerging markets, for example in gas sensing and atom cooling.Read moreRead less
A brighter future: the pure-quartic soliton laser. This project aims to build an innovative, ultrafast laser based on the recent discovery of pure-quartic solitons, a new class of optical soliton. Investigating these solitons in their own right will provide new insights into the physics of soliton formation and propagation. The concept of the pure-quartic soliton laser is expected to lead to the transformation of ultrafast science and related applications with the benefit of to improving efficie ....A brighter future: the pure-quartic soliton laser. This project aims to build an innovative, ultrafast laser based on the recent discovery of pure-quartic solitons, a new class of optical soliton. Investigating these solitons in their own right will provide new insights into the physics of soliton formation and propagation. The concept of the pure-quartic soliton laser is expected to lead to the transformation of ultrafast science and related applications with the benefit of to improving efficiency, and significantly reducing the cost of high-energy ultrafast lasers. The project aims to provide benefits in ultrafast science, industrial materials processing, laser surgery, and molecular spectroscopy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101432
Funder
Australian Research Council
Funding Amount
$372,520.00
Summary
Dissipative soliton lasers: innovative approach to high-energy femtosecond pulse generation. The generation of high-energy, ultrashort pulses will benefit various sectors in science and technology, including fabrication of nanomaterials and precise laser surgery. The dissipative soliton approach is presently recognised as one of the most useful techniques for the design of laser systems. This project will provide a roadmap for designing a novel class of laser systems that can generate high-energ ....Dissipative soliton lasers: innovative approach to high-energy femtosecond pulse generation. The generation of high-energy, ultrashort pulses will benefit various sectors in science and technology, including fabrication of nanomaterials and precise laser surgery. The dissipative soliton approach is presently recognised as one of the most useful techniques for the design of laser systems. This project will provide a roadmap for designing a novel class of laser systems that can generate high-energy femtosecond pulses.Read moreRead less
Untangling Complex Molecular Spectra with an Optical Frequency Comb. The exhaled breath is a rich source of information about the inner life of the human body - but untangling this complicated molecular mixture into a quantitative measurement of its constituent components is currently an unsolved problem. This project aims to develop a new instrument that leverages the Nobel Prize winning technology of the optical frequency comb to enable analysis of such mixtures. It is expected that by combini ....Untangling Complex Molecular Spectra with an Optical Frequency Comb. The exhaled breath is a rich source of information about the inner life of the human body - but untangling this complicated molecular mixture into a quantitative measurement of its constituent components is currently an unsolved problem. This project aims to develop a new instrument that leverages the Nobel Prize winning technology of the optical frequency comb to enable analysis of such mixtures. It is expected that by combining a frequency comb source, with an innovative detector and a highly sensitive sampling system, a real-time spectral signature of each sample will be generated. Computational techniques developed by the radio astronomy community will then be used to extract concentrations of individual molecular components at the parts-per-billion level.Read moreRead less
Ultra-fast serialised all optical image processing: addressing the electronic bottleneck in the world's fastest camera. Serial time encoded amplified microscopy can capture over a million frames per second. At this rate, a megapixel image would fill a terabyte hard disk in a second. We will use photonics to condense and manipulated the video stream so that only the important features are 'seen', making it practical to process and store on a computer.
Discovery Early Career Researcher Award - Grant ID: DE210101904
Funder
Australian Research Council
Funding Amount
$385,322.00
Summary
Next-Generation LIDAR with Novel Microresonator Frequency Combs. This project aims to develop the science that would enable a new low-cost laser radar (LIDAR) for imaging the world around us. LIDAR has applications in facial recognition, forestry and autonomous vehicles – our new device will uniquely offer the ability to work underwater thereby opening up new possibilities for maritime environmental and vehicle monitoring. Our approach exploits a new form of optical pulse propagation in precise ....Next-Generation LIDAR with Novel Microresonator Frequency Combs. This project aims to develop the science that would enable a new low-cost laser radar (LIDAR) for imaging the world around us. LIDAR has applications in facial recognition, forestry and autonomous vehicles – our new device will uniquely offer the ability to work underwater thereby opening up new possibilities for maritime environmental and vehicle monitoring. Our approach exploits a new form of optical pulse propagation in precisely shaped crystals to generate bespoke laser pulses that enable high-speed and precise ranging to targets of interest. The science behind these new types of optical pulses offers the ability for Australia to lead a new scientifically and industrially important field.Read moreRead less
Terahertz lasers in the fight against illicit substances. This project aims to investigate the application of cutting-edge terahertz laser technology with new spectroscopic methods, for detection of illicit substances. Using a collaborative approach, the project aims to bring together expertise in laser physics, spectroscopy, law enforcement and instrumentation, and seeks to develop new sources and detection protocols which will offer new capabilities to law enforcement, aiding in detection and ....Terahertz lasers in the fight against illicit substances. This project aims to investigate the application of cutting-edge terahertz laser technology with new spectroscopic methods, for detection of illicit substances. Using a collaborative approach, the project aims to bring together expertise in laser physics, spectroscopy, law enforcement and instrumentation, and seeks to develop new sources and detection protocols which will offer new capabilities to law enforcement, aiding in detection and identification protocols for illicit substances.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100509
Funder
Australian Research Council
Funding Amount
$436,482.00
Summary
Going Fourth: ruling light with pure-quartic solitons. This project aims to develop a novel integrated high-energy light source through the combination of nanoscience and optics. The core research of this project addresses the energy limitation inherent to the current technology which has hindered its use in real applications. Expected outcomes include new knowledge, with publication in world-class scientific journals, and disruptive technological capabilities in miniaturized photonics. The expe ....Going Fourth: ruling light with pure-quartic solitons. This project aims to develop a novel integrated high-energy light source through the combination of nanoscience and optics. The core research of this project addresses the energy limitation inherent to the current technology which has hindered its use in real applications. Expected outcomes include new knowledge, with publication in world-class scientific journals, and disruptive technological capabilities in miniaturized photonics. The expected benefit is to generate high-energy pulses from a battery powered micro-chip that could enhance spectroscopy sensing devices for real-world applications, outside laboratories. This project will strengthen Australian capabilities and expertise in cutting-edge nanotechnology and photonics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101721
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Probing the excited states of organic semiconductor systems with photoinduced absorption spectroscopy. Plastic semiconductors have the potential to revolutionise consumer electronics by enabling cheap, flexible and low power devices. The success of these devices depends on our understanding of the optical and electronic properties of the materials, which this project aims to address through the use of photoinduced absorption spectroscopy.
Versatile ultrafast Raman laser sources for biophotonics. Ultrafast laser pulses (lasting a billionth of a millisecond) are vital scientific tools. In partnership with a manufacturer of ultrafast lasers, the project will develop new wavelength-versatile and robust ultrafast laser sources to enable new technologies in areas such as the study of diseases at the cellular level and micron precision drug activation.