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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: DE220101548
Funder
Australian Research Council
Funding Amount
$415,000.00
Summary
Calming the Superfluid Storm: Taming Turbulence in Superfluid Devices. Turbulence, the chaotic flow of fluids, occurs in the vast majority of fluid flows in nature. This project aims to develop a new understanding of turbulence in superfluids, a class of quantum fluids which can flow without friction. The significance is that aspects of turbulence are universal, so that discoveries in superfluid turbulence will provide fundamental insights into all forms of turbulence. The expected outcomes are ....Calming the Superfluid Storm: Taming Turbulence in Superfluid Devices. Turbulence, the chaotic flow of fluids, occurs in the vast majority of fluid flows in nature. This project aims to develop a new understanding of turbulence in superfluids, a class of quantum fluids which can flow without friction. The significance is that aspects of turbulence are universal, so that discoveries in superfluid turbulence will provide fundamental insights into all forms of turbulence. The expected outcomes are solutions to two outstanding questions – what are the universal laws of turbulent flow for superfluids, and what new forms of quantum vortex matter are possible? New insights into turbulence will benefit all applications which rely on its understanding, for example in medicine, aviation, and climate modelling.Read moreRead less
A Quantum Matterwave Vortex Gyroscope for Ultrastable Rotation Sensing. This project aims to investigate the basic science underpinning a new rotation sensing technology based on matterwave vortices. Current gyroscopes are susceptible to long-term calibration drifts, which limit their applicability on long timescales where re-calibration is not practical or possible. This project expects to build a matterwave vortex gyroscope and demonstrate that it offers unparalleled long-term stability over ` ....A Quantum Matterwave Vortex Gyroscope for Ultrastable Rotation Sensing. This project aims to investigate the basic science underpinning a new rotation sensing technology based on matterwave vortices. Current gyroscopes are susceptible to long-term calibration drifts, which limit their applicability on long timescales where re-calibration is not practical or possible. This project expects to build a matterwave vortex gyroscope and demonstrate that it offers unparalleled long-term stability over `classical’ gyroscopes based on mechanical and/or optical technology. This could deliver new navigation capabilities, benefitting Australia’s defence forces and nascent space technology industry, as well as enabling slow timescale precision gravimetry for mineral exploration, hydrology, and geology. 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
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
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
Discovery Early Career Researcher Award - Grant ID: DE130100575
Funder
Australian Research Council
Funding Amount
$373,944.00
Summary
Quantum enhancement for ultra-precise atomic sensors. This project will investigate methods for drastically improving the sensitivity of measurement devices derived from atom interferometers. This will enable experimental tests of certain aspects of fundamental physics, as well as practical tools such as ultra-precise geodesy for minerals exploration.
Quantum thermodynamics of ultra-cold atoms. This project aims to provide new knowledge about the relationships between energy, entropy and information in the quantum realm of nanoscale machines and few-atoms systems. The Second Quantum Revolution is currently underway, and represents the merging of thermodynamic concepts of heat and work, with quantum concepts of information processing and entanglement. The project intends to shed light on how classical ideas on the nature of heat and work trans ....Quantum thermodynamics of ultra-cold atoms. This project aims to provide new knowledge about the relationships between energy, entropy and information in the quantum realm of nanoscale machines and few-atoms systems. The Second Quantum Revolution is currently underway, and represents the merging of thermodynamic concepts of heat and work, with quantum concepts of information processing and entanglement. The project intends to shed light on how classical ideas on the nature of heat and work translate to quantum devices. The knowledge arising from the project is expected to underpin experimental breakthroughs in the field and aid the development of new quantum technologies. The benefits lie in informing the design of new energy-efficient quantum materials, making future quantum technologies thermodynamically viable, and strengthening Australia's capacity to develop a modern, knowledge-based economy.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL180100155
Funder
Australian Research Council
Funding Amount
$2,815,901.00
Summary
A molecular quantum simulator. This project will create a molecular quantum simulator to address outstanding questions in the fields of superconductivity, superfluidity, quantum magnetism, topological quantum matter, and quantum non-equilibrium physics. This project will enable Australia to compete with other nations’ efforts to build quantum technologies that are enabled by cold atom and cold molecule physics for future needs in simulation, computing, sensing and metrology.
ARC Centre of Excellence in Future Low Energy Electronics Technologies. This Centre aims to develop the scientific foundation and intellectual property for new electronics technologies. Decreasing energy use is a major societal challenge, and this Centre aims to meet that challenge by realising fundamentally new types of electronic conduction without resistance in solid-state systems at room temperature. Novel resistance-free electronic phenomena at room temperature are expected to form the basi ....ARC Centre of Excellence in Future Low Energy Electronics Technologies. This Centre aims to develop the scientific foundation and intellectual property for new electronics technologies. Decreasing energy use is a major societal challenge, and this Centre aims to meet that challenge by realising fundamentally new types of electronic conduction without resistance in solid-state systems at room temperature. Novel resistance-free electronic phenomena at room temperature are expected to form the basis of integrated electronics technology with ultra-low energy consumption. This Centre’s development of innovative electronics could put Australia at the forefront of the international electronics industry.Read moreRead less