Discovery Early Career Researcher Award - Grant ID: DE180100781
Funder
Australian Research Council
Funding Amount
$343,450.00
Summary
Strong few-body correlations from controllable impurities in quantum matter. This project aims to investigate the role of few-body correlations in quantum matter by using recently developed theoretical approaches to incorporate correlations beyond the scope of traditional theories. The project expects to gain fundamental insight into quantum few-body correlations in materials by investigating single impurity particles immersed in quantum media, such as highly controllable atomic gases and semico ....Strong few-body correlations from controllable impurities in quantum matter. This project aims to investigate the role of few-body correlations in quantum matter by using recently developed theoretical approaches to incorporate correlations beyond the scope of traditional theories. The project expects to gain fundamental insight into quantum few-body correlations in materials by investigating single impurity particles immersed in quantum media, such as highly controllable atomic gases and semiconductors. The significant benefits include the development of novel theoretical approaches and the generation of knowledge that could potentially underpin a new generation of quantum devices.Read moreRead less
Density modulations and superconductivity in two-dimensional quantum gases. The project aims to investigate the interplay between pairing (superfluidity) and pattern formation (eg stripes) in quasi-two-dimensional quantum systems. The close proximity of these phases is a recurring theme in layered materials which could hold the key to understanding phenomena such as high temperature superconductivity. The project plans to investigate these phases in dipolar gases, which provide a clean, controll ....Density modulations and superconductivity in two-dimensional quantum gases. The project aims to investigate the interplay between pairing (superfluidity) and pattern formation (eg stripes) in quasi-two-dimensional quantum systems. The close proximity of these phases is a recurring theme in layered materials which could hold the key to understanding phenomena such as high temperature superconductivity. The project plans to investigate these phases in dipolar gases, which provide a clean, controlled environment for novel many-body phenomena. Within this setting, it plans to test established theories of pairing and develop accurate descriptions of density modulations, thus providing fundamental insights into strongly correlated systems. The new states of matter discovered in the project could form the basis for new quantum devices; in particular, a deeper understanding of stripe phases may allow us to use them for data storage.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
Few-body correlations in many-particle quantum matter. This project aims to develop theories of quantum matter by investigating the connection between microscopic few-particle correlations and macroscopic quantum phenomena. The growing class of strongly correlated quantum systems that defy a conventional explanation creates a pressing need for this approach. This project will use the clean and tuneable cold-atom system, where microscopic properties are precisely known, to directly verify new spe ....Few-body correlations in many-particle quantum matter. This project aims to develop theories of quantum matter by investigating the connection between microscopic few-particle correlations and macroscopic quantum phenomena. The growing class of strongly correlated quantum systems that defy a conventional explanation creates a pressing need for this approach. This project will use the clean and tuneable cold-atom system, where microscopic properties are precisely known, to directly verify new spectral techniques. A greater understanding of quantum correlations is expected to advance several fields including condensed matter physics, and could underpin quantum devices where energy can be efficiently stored and rapidly extracted.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102495
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Creation, detection, and decoherence of a "Schrödinger Cat". Ultra-cold physics is a new frontier of science, especially Bose-Einstein condensates, as mesoscopic quantum objects, are expected to have a revolutionary impact on future science and technology. This project aims to test the famous quantum mechanical prediction the "Schrödinger Cat" (neither dead nor alive) using ultra-cold physics.
ARC Centre of Excellence for Quantum Computation and Communication Technology. This Centre aims to implement quantum processors able to run error corrected algorithms and transfer information across networks with absolute security. Australian researchers have established global leadership in quantum information, an innovative technology which could transform all industries dependent on computational power. This Centre has developed technologies for manipulating matter and light at the level of i ....ARC Centre of Excellence for Quantum Computation and Communication Technology. This Centre aims to implement quantum processors able to run error corrected algorithms and transfer information across networks with absolute security. Australian researchers have established global leadership in quantum information, an innovative technology which could transform all industries dependent on computational power. This Centre has developed technologies for manipulating matter and light at the level of individual atoms and photons, with the highest fidelity, longest coherence time qubits in the solid state, the world’s longest-lived quantum memory, and the ability to run small-scale algorithms on photonic qubits. The new technology is expected to provide a strategic advantage in a world where information and information security are of paramount importance.Read moreRead less
ARC Centre of Excellence for Quantum Computation and Communication Technology. The Centre for Quantum Computation and Communication Technology will coordinate a large team of Australian researchers in an intensive mission. Our aim is to integrate a radical and uniquely powerful Australian computing technology with an ultra-secure Australian communications technology. Our success will drive global productivity gains in information processing and ensure that Australians own the pivotal underpinnin ....ARC Centre of Excellence for Quantum Computation and Communication Technology. The Centre for Quantum Computation and Communication Technology will coordinate a large team of Australian researchers in an intensive mission. Our aim is to integrate a radical and uniquely powerful Australian computing technology with an ultra-secure Australian communications technology. Our success will drive global productivity gains in information processing and ensure that Australians own the pivotal underpinning intellectual property. Our technologies will provide Australia and its allies with the world's most secure information networks. Our discoveries will place Australia unequivocally at the very forefront of global research in quantum physicsRead moreRead less
Quantum properties of high-spin ultra-cold matter. High-spin atomic gases are a new type of ultra-cold matter, with many unique properties akin to the physics of the early universe. The aim of the project is to theoretically investigate these systems to understand the quantum properties and dynamics of such exotic matter, and to obtain experimentally testable predictions.