Quantum limits in measurement and communication. By manipulating atoms and single particles of light, quantum technologies promise a revolution in communications systems and high-precision measurements for scientific and engineering applications. The benefits of this revolution may be comparable with those of modern semiconductors. This project will bring these benefits closer by achieving the fundamental limits to measurement allowed by quantum physics, and harnessing the power of these measure ....Quantum limits in measurement and communication. By manipulating atoms and single particles of light, quantum technologies promise a revolution in communications systems and high-precision measurements for scientific and engineering applications. The benefits of this revolution may be comparable with those of modern semiconductors. This project will bring these benefits closer by achieving the fundamental limits to measurement allowed by quantum physics, and harnessing the power of these measurements for communication. It will also identify ways to simplify potential quantum technologies, hastening their adoption. This research will place Australian theoretical and experimental researchers at the forefront of 21st century technology.Read moreRead less
Robust quantum information and metrology. Quantum technologies promise a revolution in computing speed and measurement precision, but are currently sensitive to noise and difficult to demonstrate on a large scale. This project will develop practical solutions to these problems, providing a clear path to future production of large-scale quantum technologies.
Fundamental quantum science for advancing optical quantum technologies. Quantum science promises a technology revolution comparable to the emergence of the information age. This project will advance the quantum technology revolution by uncovering new concepts in fundamental quantum science, and applying them to the development of absolutely secure communications, ultraprecise measurements, and ultrafast information processing.
Frequency standards with breakthrough performance: engineering immunity to local oscillator instabilities using dynamical error suppression. This project aims to dramatically advance state-of-the-art performance of one of the most important technological systems in modern electronics - precision frequency standards. Our work will provide orders of magnitude gains in performance by translating new knowledge from quantum information to the precision metrology research community.