Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100040
Funder
Australian Research Council
Funding Amount
$699,664.00
Summary
Multifunctional deposition system for advanced superconducting circuits. This project aims to create a one-stop facility to enhance Australia’s capacity to develop superconducting quantum technology centred on the unique capabilities of a Multifunctional Deposition System. The project will enable and expedite nanofabrication of complex circuits and expects to pioneer novel superconducting and hybrid quantum technologies, and high-tech classical devices for clean-energy and biomedical application ....Multifunctional deposition system for advanced superconducting circuits. This project aims to create a one-stop facility to enhance Australia’s capacity to develop superconducting quantum technology centred on the unique capabilities of a Multifunctional Deposition System. The project will enable and expedite nanofabrication of complex circuits and expects to pioneer novel superconducting and hybrid quantum technologies, and high-tech classical devices for clean-energy and biomedical applications. Expected outcomes include robust multi-institutional and cross-disciplinary collaborations, and increased translation between cutting-edge theory and commercial prototypes. Benefits should include stronger industry engagement, training for next-generation innovators and a boost to Australian advanced manufacturing.Read moreRead less
Integrating quantum hyperpolarisation in nuclear magnetic resonance systems. This project aims to integrate quantum hyperpolarisation technology into state-of-the-art nuclear magnetic resonance (NMR) systems, potentially boosting the signal by several orders of magnitude. Understanding the structure and function of membrane bound peptides and proteins in cells in their native environments is critical in drug development. However, studying these biomolecules by conventional NMR under ambient cond ....Integrating quantum hyperpolarisation in nuclear magnetic resonance systems. This project aims to integrate quantum hyperpolarisation technology into state-of-the-art nuclear magnetic resonance (NMR) systems, potentially boosting the signal by several orders of magnitude. Understanding the structure and function of membrane bound peptides and proteins in cells in their native environments is critical in drug development. However, studying these biomolecules by conventional NMR under ambient conditions is challenging due to sensitivity limitations. The technology developed by this project will be a significant step forward in NMR and the new science enabled may have far reaching consequences for the study of peptides and proteins of live cells for the development of new drugs and anti-biotics, with direct societal benefits and flow-on economic benefits.Read moreRead less
Simulation of exponentially complex quantum technologies. This project aims to develop computational tools to study exponentially complex many-body systems, and use them to model novel quantum technologies. Physics has a deep and broad impact on our modern lives, via computing, the internet, mobile telephones, GPS, space travel and medical technologies. This project will demonstrate the potential of quantum devices, with significance and impact both inside and outside physics. The project will s ....Simulation of exponentially complex quantum technologies. This project aims to develop computational tools to study exponentially complex many-body systems, and use them to model novel quantum technologies. Physics has a deep and broad impact on our modern lives, via computing, the internet, mobile telephones, GPS, space travel and medical technologies. This project will demonstrate the potential of quantum devices, with significance and impact both inside and outside physics. The project will simulate quantum systems ranging from quantum circuits for early universe simulation to boson sampling devices using Bose-Einstein condensates and plasmonic systems. Through modelling recent advances, and proposing robust, ultra-sensitive interferometers as one application, the project expects to enhance capability and understanding of quantum science.Read moreRead less
ARC Centre of Excellence for Engineered Quantum Systems. This Centre aims to build sophisticated quantum machines to harness the quantum world for the future health, economy, environment and security of Australian society. It intends to pioneer the designer quantum materials, engines and imaging systems at the heart of these machines. It also solves the most challenging research problems at the interface of basic quantum physics and engineering. The Centre will work with industry partners to tra ....ARC Centre of Excellence for Engineered Quantum Systems. This Centre aims to build sophisticated quantum machines to harness the quantum world for the future health, economy, environment and security of Australian society. It intends to pioneer the designer quantum materials, engines and imaging systems at the heart of these machines. It also solves the most challenging research problems at the interface of basic quantum physics and engineering. The Centre will work with industry partners to translate these research discoveries into practical applications and devices. It will train scientists in research, innovation, and entrepreneurship, which is expected to affect Australia’s high-tech economy.Read moreRead less
An atom-scale fabrication technique for diamond quantum microprocessors. This project aims to develop an atomically-precise fabrication technique for the production of diamond quantum microprocessors through the pursuit of a novel bottom-up approach. This project expects to create significant new knowledge and capability in precision diamond growth, surface chemistry, electronics and characterisation, establish a long-term strategic partnership between Quantum Brilliance and the participating or ....An atom-scale fabrication technique for diamond quantum microprocessors. This project aims to develop an atomically-precise fabrication technique for the production of diamond quantum microprocessors through the pursuit of a novel bottom-up approach. This project expects to create significant new knowledge and capability in precision diamond growth, surface chemistry, electronics and characterisation, establish a long-term strategic partnership between Quantum Brilliance and the participating organisations, and enable the realisation of high-performance quantum microprocessors. These outcomes will potentially deliver Australia and Quantum Brilliance a profound advantage in quantum computing, thereby securing their positions in the emerging global quantum market and the associated economic and security benefits.Read moreRead less
Gravity and quantum-limited measurements with a fundamental minimum length. This project aims to investigate the effects of a fundamental minimum length on the nature of gravity and on how accurately we can make measurements in our world. The key challenge is to combine our best theories of fundamental physics to model what happens at ultra-short distances. This project will generate new knowledge at this interface by using a novel approach inspired by information theory. The expected outcomes a ....Gravity and quantum-limited measurements with a fundamental minimum length. This project aims to investigate the effects of a fundamental minimum length on the nature of gravity and on how accurately we can make measurements in our world. The key challenge is to combine our best theories of fundamental physics to model what happens at ultra-short distances. This project will generate new knowledge at this interface by using a novel approach inspired by information theory. The expected outcomes are new connections between fundamental limitations on measurements, the nature of gravitation, and ultra-small-scale quantum physics. The benefit of this work is breaking the logjam in answering the most important open question in all of physics: how to unite quantum theory and gravitation.Read moreRead less
Quantum measurement as a resource. Advanced quantum computers will use modular measurements significantly enhancing their capabilities. However, due to the noisy environment, the measurements may have nontrivial effects on the computation. Making best use of realistic (hence imperfect) measurements is a challenging problem that hinders the development of these technologies. This project, using modern tools of resource theory, aims to design optimal realistic measurement procedures for near-term ....Quantum measurement as a resource. Advanced quantum computers will use modular measurements significantly enhancing their capabilities. However, due to the noisy environment, the measurements may have nontrivial effects on the computation. Making best use of realistic (hence imperfect) measurements is a challenging problem that hinders the development of these technologies. This project, using modern tools of resource theory, aims to design optimal realistic measurement procedures for near-term noisy quantum devices. The expected outcomes of the project are refined methods to optimise quantum measurements in today's rudimentary quantum machines. This will provide a significant benefit to the Australian community, advancing the development of disruptive quantum technologies.Read moreRead less
Agile synthesizers for quantum computing, simulation and sensing. The project aims to develop breakthrough technology for generating the complex radio and microwave pulses that underpin the revolution in quantum computing and quantum sensing. Quantum technologies are rapidly emerging from laboratory to real-world applications including neural imaging, defence surveillance, and mining exploration, but further advances require increased precision and flexibility in controlling the quantum states ....Agile synthesizers for quantum computing, simulation and sensing. The project aims to develop breakthrough technology for generating the complex radio and microwave pulses that underpin the revolution in quantum computing and quantum sensing. Quantum technologies are rapidly emerging from laboratory to real-world applications including neural imaging, defence surveillance, and mining exploration, but further advances require increased precision and flexibility in controlling the quantum states at the heart of these new capabilities. Our innovative and more flexible approach to signal generation requires a fraction of the size, weight, power and cost of conventional approaches, enabling the translation of quantum technology to commercial practicality.Read moreRead less
Building time crystals with ultracold atoms. This project aims to create a new exotic form of quantum matter in which a many-body system of ultracold atoms bouncing on a vibrating mirror spontaneously self-organises its motion with a period tens of times longer than the driving period of the mirror. Such ‘time crystals’ are predicted to be robust against external perturbations and to persist for very long times. The project expects to generate new knowledge on exotic non-equilibrium crystalline ....Building time crystals with ultracold atoms. This project aims to create a new exotic form of quantum matter in which a many-body system of ultracold atoms bouncing on a vibrating mirror spontaneously self-organises its motion with a period tens of times longer than the driving period of the mirror. Such ‘time crystals’ are predicted to be robust against external perturbations and to persist for very long times. The project expects to generate new knowledge on exotic non-equilibrium crystalline phenomena in the time domain, such as many-body localisation with temporal disorder, which has counter-intuitive characteristics such as absence of thermalisation and vanishing direct current transport. Time crystals could provide significant benefits for the storage and transfer of quantum information, and this, and other outcomes may ultimately lead to commercial products.Read moreRead less
The nature and fate of quasiparticles in correlated quantum matter. The revolution in electronics and the Information Age were enabled by powerful theories based on the concept of the quasiparticle, an object composed of many particles such as electrons. This Fellowship aims to unravel the behaviour of new complex materials by investigating the nature of quasiparticles beyond the current paradigm. The key innovation is the use of trapped atoms, which allows new quantum theories and computational ....The nature and fate of quasiparticles in correlated quantum matter. The revolution in electronics and the Information Age were enabled by powerful theories based on the concept of the quasiparticle, an object composed of many particles such as electrons. This Fellowship aims to unravel the behaviour of new complex materials by investigating the nature of quasiparticles beyond the current paradigm. The key innovation is the use of trapped atoms, which allows new quantum theories and computational tools to be developed and precisely tested. The new knowledge generated by the Fellowship will advance a range of fields, including condensed matter physics, and could ultimately underpin a new generation of quantum devices featuring robust data memories, where information can be efficiently stored and extracted.Read moreRead less