Instrumentation for the era of gravitational wave science. This project aims to study noise sources that limit the low-frequency performance of gravitational wave antenna: thermal noise, quantum radiation pressure noise and Newtonian noise. Gravitational wave detection is a new way in which to observe our universe. Although detectors such as advanced LIGO (Laser Interferometer Gravitational-Wave Observatory) should detect gravitational waves, further sensitivity improvement, particularly at low ....Instrumentation for the era of gravitational wave science. This project aims to study noise sources that limit the low-frequency performance of gravitational wave antenna: thermal noise, quantum radiation pressure noise and Newtonian noise. Gravitational wave detection is a new way in which to observe our universe. Although detectors such as advanced LIGO (Laser Interferometer Gravitational-Wave Observatory) should detect gravitational waves, further sensitivity improvement, particularly at low frequencies, will be needed to provide event rates necessary for astronomy. Expected project outcomes will support the development of the first free mass interferometer to operate at 120K using silicon optics, a vital facility for the world community. Pushing the boundaries of measurement may also drive innovation in optical sensing with potential applications in defence, security and exploration.Read moreRead less
Quantum satellites: safeguarding space-based communication networks. This project aims to address the fundamental challenges of developing quantum communication technology in space by performing space qualification of quantum technologies and optimising quantum-key distribution protocols for space applications. The project expects to generate new knowledge in the area of long-distance quantum key distribution based on continuous variables providing Australia with secure information networks. Exp ....Quantum satellites: safeguarding space-based communication networks. This project aims to address the fundamental challenges of developing quantum communication technology in space by performing space qualification of quantum technologies and optimising quantum-key distribution protocols for space applications. The project expects to generate new knowledge in the area of long-distance quantum key distribution based on continuous variables providing Australia with secure information networks. Expected outcomes of the project include licensing of key patents in building a quantum toolkit for space applications, establishment of collaboration across research institutes and disciplines, defence organisations and industry partners.Read moreRead less