Optomechanical refrigeration of electronic circuits. The project aims to apply laser light to reduce the temperature of electronic circuits. This aims to greatly suppress electronic noise, and enable a new class of technologies for future telecommunication systems. By developing new techniques to confine light, electric fields and vibrations at sub-micron scale on a silicon chip, devices such as ultralow noise amplifiers, clocks and radio frequency receivers will be realised, along with ultra-ef ....Optomechanical refrigeration of electronic circuits. The project aims to apply laser light to reduce the temperature of electronic circuits. This aims to greatly suppress electronic noise, and enable a new class of technologies for future telecommunication systems. By developing new techniques to confine light, electric fields and vibrations at sub-micron scale on a silicon chip, devices such as ultralow noise amplifiers, clocks and radio frequency receivers will be realised, along with ultra-efficient optical modulators. In future, these technologies could reduce energy consumption and improve reliability in telecommunication networks. They could improve the range of satellite communication, robustness of GPS against cosmic radiation, and performance of surveillance systems such as radar and sonar.Read moreRead less
Ultraprecise sensing with microcavity optomechanics. New technologies will be developed to observe nanoscale motion with light confined on a silicon chip. Based on advances in integrated photonics and nanofabrication, these technologies will enable microscale magnetic field, mass, and gas sensing with precision surpassing today’s state-of-the-art. Important proof-of-principle applications will be realised, including ultrasensitive monitoring of greenhouse emissions, hydrogen absorption into fuel ....Ultraprecise sensing with microcavity optomechanics. New technologies will be developed to observe nanoscale motion with light confined on a silicon chip. Based on advances in integrated photonics and nanofabrication, these technologies will enable microscale magnetic field, mass, and gas sensing with precision surpassing today’s state-of-the-art. Important proof-of-principle applications will be realised, including ultrasensitive monitoring of greenhouse emissions, hydrogen absorption into fuel cell materials, space communication technologies, and magnetic resonance techniques for diagnosis of disease and airport security. The capacity to observe microscopic processes with record precision will further enable fundamental studies in areas such as condensed matter physics and photosynthesis.Read moreRead less
ARC Centre of Excellence for Transformative Meta-Optical Systems. The ARC Centre of Excellence for Transformative Meta-Optical Systems will develop the next-generation of miniaturised optical systems with functionalities beyond what is conceivable today. By harnessing the disruptive concept of meta-optics, the Centre will overcome complex challenges in light generation, manipulation and detection at the nanoscale. The Centre brings together a trans-disciplinary team of world-leaders in science, ....ARC Centre of Excellence for Transformative Meta-Optical Systems. The ARC Centre of Excellence for Transformative Meta-Optical Systems will develop the next-generation of miniaturised optical systems with functionalities beyond what is conceivable today. By harnessing the disruptive concept of meta-optics, the Centre will overcome complex challenges in light generation, manipulation and detection at the nanoscale. The Centre brings together a trans-disciplinary team of world-leaders in science, technology and engineering to deliver scientific innovations in optical systems for the Fourth Industrial Revolution. The research outcomes will underpin future technologies, including real-time holographic displays, artificial vision for autonomous systems to see the invisible, and ultra-fast light-based WiFi.Read moreRead less