Crossing quantum-classical boundaries in a single particle. This project is aimed at constructing and observing an individual quantum system that can exhibit chaotic behaviour under controllable conditions. It is a long-sought goal of modern physics that can become reality for the first time in the world, thanks to the unique availability in Australia of the most quantum-coherent single spin ever made and a long history of theoretical advances in the field. Turning a spin into a chaotic system w ....Crossing quantum-classical boundaries in a single particle. This project is aimed at constructing and observing an individual quantum system that can exhibit chaotic behaviour under controllable conditions. It is a long-sought goal of modern physics that can become reality for the first time in the world, thanks to the unique availability in Australia of the most quantum-coherent single spin ever made and a long history of theoretical advances in the field. Turning a spin into a chaotic system will uncover the true nature of the quantum-classical boundary, and verify whether an underlying classical chaotic dynamics ultimately influences the behaviour of quantum systems. It is expected that the discoveries made will illuminate the path towards the technological exploitation of increasingly complex quantum devices.Read moreRead less
Outmaneuvering correlated noise in quantum computers. The project aims to characterise and control quantum machines available today. These machines overwhelmingly suffer from noise with complex structures. Thus, a key target of the project is to develop a theory to describe and manipulate complex quantum processes. The project then intends to apply this theory to commercial-grade quantum computers. This approach is anticipated to lead to a new understanding of time-correlated complex quantum pro ....Outmaneuvering correlated noise in quantum computers. The project aims to characterise and control quantum machines available today. These machines overwhelmingly suffer from noise with complex structures. Thus, a key target of the project is to develop a theory to describe and manipulate complex quantum processes. The project then intends to apply this theory to commercial-grade quantum computers. This approach is anticipated to lead to a new understanding of time-correlated complex quantum processes and develop methods to enhance the performance of today's quantum computers. Noise characterisation and mitigation should have commercial value and benefit research groups working to develop quantum technologies, both in Australia and internationally.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
Complex quantum dynamics for technological applications. This project aims to characterise dynamics of a quantum system immersed in a complex surrounding, such as a quantum computer interacting with an environment that remembers the computer’s past. Since there are no known methods for battling the effects of the environment on the computer when they are intertwined, this project will develop tools to combat these adverse effects. The project will discover physics of complex dynamics and investi ....Complex quantum dynamics for technological applications. This project aims to characterise dynamics of a quantum system immersed in a complex surrounding, such as a quantum computer interacting with an environment that remembers the computer’s past. Since there are no known methods for battling the effects of the environment on the computer when they are intertwined, this project will develop tools to combat these adverse effects. The project will discover physics of complex dynamics and investigate unexplored physical phenomena in the laboratory, like an antenna of photosynthetic systems that use complex surroundings for efficient and fast energy transport. The project is expected to help build new and improved quantum machines.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
Imaging Light and Gases with Low Energy Electrons. The imaging of light and atoms trapped in the potential minima of optical lattices will be a world first, positioning Australia at the forefront of the merging fields of electron microscopy and atom optics, leading to important international recognition and publicity. This project, relevant to the frontier technologies of photonics, atom optics and quantum information processing, will also develop a skills base in surface electron microscopy and ....Imaging Light and Gases with Low Energy Electrons. The imaging of light and atoms trapped in the potential minima of optical lattices will be a world first, positioning Australia at the forefront of the merging fields of electron microscopy and atom optics, leading to important international recognition and publicity. This project, relevant to the frontier technologies of photonics, atom optics and quantum information processing, will also develop a skills base in surface electron microscopy and laser science by providing high level training for post-graduate and honours students. In addition, the utilisation of optical lattices as micro-environmental cells in electron microscopy will be an important development for in situ studies of the gas phase including chemical reactions.
Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100647
Funder
Australian Research Council
Funding Amount
$385,155.00
Summary
Spin-Orbit coupling in a Lithium-6 quasi-2D Fermi gas. Spin-orbit interactions couple a particle's spin to its momentum and underlie remarkable phenomena including topological edge states in insulators and the fractional quantum Hall effect. In conventional solid-state systems these effects are difficult to study due to the complex and imperfect structure of the host material. This project will generate spin-orbit coupling in the defect free and highly controllable environment of an ultracold qu ....Spin-Orbit coupling in a Lithium-6 quasi-2D Fermi gas. Spin-orbit interactions couple a particle's spin to its momentum and underlie remarkable phenomena including topological edge states in insulators and the fractional quantum Hall effect. In conventional solid-state systems these effects are difficult to study due to the complex and imperfect structure of the host material. This project will generate spin-orbit coupling in the defect free and highly controllable environment of an ultracold quasi-two-dimensional Fermi gas to observe new topological phases and Majorana fermions which hold promise for realising decoherence free protected quantum states. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100142
Funder
Australian Research Council
Funding Amount
$727,900.00
Summary
Australian quantum gas microscope. This project aims to create a quantum gas microscope for ultra-cold dysprosium atoms, realising a versatile system for quantum emulation, tests of fundamental, atom interferometry, and precision measurement. Quantum gas microscopy is a frontier area allowing atom-by-atom synthesis and probing of tailored quantum materials such as topological insulators. Using the lanthanide element dysprosium, which is highly magnetic and possesses both bosonic and fermionic is ....Australian quantum gas microscope. This project aims to create a quantum gas microscope for ultra-cold dysprosium atoms, realising a versatile system for quantum emulation, tests of fundamental, atom interferometry, and precision measurement. Quantum gas microscopy is a frontier area allowing atom-by-atom synthesis and probing of tailored quantum materials such as topological insulators. Using the lanthanide element dysprosium, which is highly magnetic and possesses both bosonic and fermionic isotopes, this facility will serve the needs of multiple research groups with diverse scientific interests.Read moreRead less
Controlling spin coherence with rotation. This project aims to harness the ability to control the fundamental interactions which limit the precision of a diamond quantum sensor, enabling more sensitive magnetometry. Quantum sensors are unveiling new insights into nano-scale phenomena. Single atom defects in diamonds have been at the forefront of this revolution in nano-scale sensor technology. A unique capability, spinning diamond quantum sensors at up to 500,000 rpm, fast enough that quantum pr ....Controlling spin coherence with rotation. This project aims to harness the ability to control the fundamental interactions which limit the precision of a diamond quantum sensor, enabling more sensitive magnetometry. Quantum sensors are unveiling new insights into nano-scale phenomena. Single atom defects in diamonds have been at the forefront of this revolution in nano-scale sensor technology. A unique capability, spinning diamond quantum sensors at up to 500,000 rpm, fast enough that quantum properties of the defects are preserved during a cycle has been established. This project will address the long-standing problem of nano-scale solid-materials characterisation using rotationally-enhanced quantum magnetic resonance spectroscopy.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