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
Discovery Early Career Researcher Award - Grant ID: DE140101700
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Integrated photonic quantum simulators for quantum chemistry. This project aims to develop the first generation quantum processors specifically designed to efficiently solve problems in quantum chemistry that are intractable on conventional computers. To remove the major limitations that plague current approaches, and achieve devices of unprecedented size and complexity, this project will use photonic technology and integrate, for the first time, all the critical components on a single chip. The ....Integrated photonic quantum simulators for quantum chemistry. This project aims to develop the first generation quantum processors specifically designed to efficiently solve problems in quantum chemistry that are intractable on conventional computers. To remove the major limitations that plague current approaches, and achieve devices of unprecedented size and complexity, this project will use photonic technology and integrate, for the first time, all the critical components on a single chip. These components are single photon sources, processing circuits and single photon detectors. The outputs of this project will have applications ranging from the design of new materials and drugs to determining the results of internet search engines.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
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
Discovery Early Career Researcher Award - Grant ID: DE200101785
Funder
Australian Research Council
Funding Amount
$424,978.00
Summary
Viewing Chemistry through Diamond: Quantum Sensors for Realtime in situ NMR. This project aims to develop a new analytical method and integrated platform technology for time dependent, in situ monitoring of chemical reactions. The proposed research will capitalise on recent developments made in the field of diamond-based quantum sensing to enable the resolution of chemical species and their concentrations within the timescales associated with many important reaction systems. This project thus ex ....Viewing Chemistry through Diamond: Quantum Sensors for Realtime in situ NMR. This project aims to develop a new analytical method and integrated platform technology for time dependent, in situ monitoring of chemical reactions. The proposed research will capitalise on recent developments made in the field of diamond-based quantum sensing to enable the resolution of chemical species and their concentrations within the timescales associated with many important reaction systems. This project thus expects to generate knowledge in both quantum metrology and physical chemistry. Moreover, the realisation of this technology has significant potential to improve the design and manufacture of important advanced materials, ranging from clean energy production and storage, to pharmaceutical development and drug discovery.Read moreRead less
Finding the lost particle: Majorana fermions in ultracold atoms. Majorana fermions – particles that are their own antiparticles – play a key role in future quantum technologies such as fault-tolerant quantum computers. Being considered only as a mathematical possibility over the past 75 years, they might be surprisingly materialised owing to recent rapid experimental advances. In collaboration with the world-leading cold-atom laboratories in Australia, China and the USA, this project aims to pav ....Finding the lost particle: Majorana fermions in ultracold atoms. Majorana fermions – particles that are their own antiparticles – play a key role in future quantum technologies such as fault-tolerant quantum computers. Being considered only as a mathematical possibility over the past 75 years, they might be surprisingly materialised owing to recent rapid experimental advances. In collaboration with the world-leading cold-atom laboratories in Australia, China and the USA, this project aims to pave a new direction to create and manipulate Majorana fermions towards realistic atomtronics devices, by using the highly controllable setting of ultracold atomic Fermi gases. This research complements the search of Majorana fermions in solid-state devices.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100055
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Quantum wires of Fermi atoms. This project aims to understand one-dimensional materials by engineering quantum wires of interacting fermions with ultracold atoms. Particles confined to move in one dimension behave differently than in three-dimensional matter, revealing quantum phases and exotic forms of superfluidity not seen in higher dimensions. Ultracold atoms allow the precise control of interactions and a perfectly isolated and defect free environment to study such phenomena not easily achi ....Quantum wires of Fermi atoms. This project aims to understand one-dimensional materials by engineering quantum wires of interacting fermions with ultracold atoms. Particles confined to move in one dimension behave differently than in three-dimensional matter, revealing quantum phases and exotic forms of superfluidity not seen in higher dimensions. Ultracold atoms allow the precise control of interactions and a perfectly isolated and defect free environment to study such phenomena not easily achieved in solid-state systems. The goal of this project is to provide quantitative insights into the thermodynamic and superfluid properties of one-dimensional quantum materials with potential significance for new innovations and applications in emerging quantum technologies.Read moreRead less
Solid Light: Frontiers and applications of solid-state Cavity Quantum Electro-Dynamics. Our understanding of quantum mechanics directly fuels new technology. We are on the verge of a new revolution in technology, where the aspects of quantum physics that we haven't been able to understand are now within technological reach. Our concept of solid-light joins two of the most important branches of physics, and in so doing develops a new technology of diamond-based quantum processors that will be b ....Solid Light: Frontiers and applications of solid-state Cavity Quantum Electro-Dynamics. Our understanding of quantum mechanics directly fuels new technology. We are on the verge of a new revolution in technology, where the aspects of quantum physics that we haven't been able to understand are now within technological reach. Our concept of solid-light joins two of the most important branches of physics, and in so doing develops a new technology of diamond-based quantum processors that will be built in Australia. This will benefit the Australian scientific community by providing devices to solve important quantum problems, and benefit the wider community by growing a new industry based around diamond quantum nanoscience.Read moreRead less
Spin-orbit coupled quantum gases: understanding new generation materials with topological order. Topological insulators and superconductors are new functional materials discovered very recently in solid-state systems. They have remarkable, topologically protected states on their surfaces that render the electrons travelling insensitive to the scattering by impurities or disorder. Their potential applications in our ordinary life are far-reaching, ranging from novel energy-saving devices to reali ....Spin-orbit coupled quantum gases: understanding new generation materials with topological order. Topological insulators and superconductors are new functional materials discovered very recently in solid-state systems. They have remarkable, topologically protected states on their surfaces that render the electrons travelling insensitive to the scattering by impurities or disorder. Their potential applications in our ordinary life are far-reaching, ranging from novel energy-saving devices to realistic quantum computers. This project will obtain greatly improved understanding of the novel topological states that underlie such new generation materials, by using the highly controllable settings of spin-orbit coupled quantum gases. It will advance Australia’s position at the forefront of ultracold atomic physics research.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101636
Funder
Australian Research Council
Funding Amount
$315,000.00
Summary
Emergent quantum phenomena in ultracold matter with artificial gauge fields. Gauge fields are central in our modern understanding of physics. They are at the origin of many sophisticated states of matter including quantum Hall materials, topological insulators and supersolids that have potential applications in future technologies. This project aims to explore these exotic quantum states emerging in ultracold atomic gases with artificially engineered gauge fields. Unlike the solid-state systems, ....Emergent quantum phenomena in ultracold matter with artificial gauge fields. Gauge fields are central in our modern understanding of physics. They are at the origin of many sophisticated states of matter including quantum Hall materials, topological insulators and supersolids that have potential applications in future technologies. This project aims to explore these exotic quantum states emerging in ultracold atomic gases with artificially engineered gauge fields. Unlike the solid-state systems, in which all details of the material structure are not controlled or even not known with certainty, the unprecedented controllability of the ultracold system provides a unique opportunity to gain key insights on the physics related to the gauge fields, and to advance the studies in both fundamental physics and applications.Read moreRead less