Professor Andrew White
Professor

Andrew White

Email: 
Phone: 
+61 7 336 57902
Phone: 
+61 7 336 53415

Background

Professor White is Director of the Australian Research Council Centre of Excellence in Engineered Quantum Systems, an Australian Research Council Laureate Fellow, and leads the Quantum Technology Laboratory at UQ, which he established in 1999. He is internationally recognised for research in quantum science and technology, and is interested in all aspects of quantum weirdness. He is a Fellow of the Australian Academy of Science, the American Physical Society, and Optica. Andrew’s research spans: quantum foundations; production, manipulation and exploitation of quantum states of light, both in conventional optics and nanophotonics; and utilising quantum technology, be it in quantum computation, quantum communication, quantum sensing, or neuromorphic computing. Details can be found at the Quantum Laboratory website.

Professor White has worked with twenty-one postdoctoral researchers since 2001, five of whom received ARC Discovery Early Career Researchers Awards whilst working in his lab, six receiving Marie Skłodowska-Curie Fellowships subsequently and one a Erwin Schrödinger Fellowship. He has supervised more than 40 postgraduate students, who have received an array of awards including a Rhodes Scholarship, three Springer PhD thesis prizes, Australian representative at the Lindau Nobel Meeting, the only-ever runner for the Australian Institute of Physics Bragg Medal, and UQ Medals and Valedictorian, to name but a few.

Bio: Andrew was raised in a Queensland dairy town, before heading south to the big smoke of Brisbane to study chemistry, maths, physics and, during the World Expo, the effects of alcohol on uni students from around the world. Deciding he wanted to know what the cold felt like, he first moved to Canberra, then Germany—completing his PhD in quantum physics—before moving on to Los Alamos National Labs in New Mexico where he quickly discovered that there is more than enough snow to hide a cactus, but not nearly enough to prevent amusing your friends when you sit down. Over the years he has conducted research on various topics including shrimp eyes, nuclear physics, optical vortices, and quantum computers. He likes quantum weirdness for its own sake, but his current research aims to explore and exploit the full range of quantum behaviours—notably entanglement—with an eye to engineering new technologies and scientific applications. He is currently Director of the Centre of Engineered Quantum Systems, an Australia-wide, 14-year long, research effort by more than 250 scientists to build quantum machines that harness the quantum world for practical applications.

Availability

Professor Andrew White is:
Available for supervision
Media expert

Fields of research

Atomic and molecular physics Atomic, molecular and optical physics Atomic, molecular and optical physics not elsewhere classified Biological physics Chemical Sciences Classical and physical optics Classical physics Engineering Foundations of quantum mechanics Information and Computing Sciences Lasers and quantum electronics Medical and biological physics Nanophotonics Nanotechnology Nonlinear optics and spectroscopy Other engineering Other engineering not elsewhere classified Other information and computing sciences Photonics, optoelectronics and optical communications Physical Sciences Quantum information, computation and communication Quantum optics and quantum optomechanics Quantum physics Quantum physics not elsewhere classified Quantum technologies Theoretical and computational chemistry

Qualifications

  • Bachelor of Science, The University of Queensland
  • Bachelor (Honours) of Science, The University of Queensland
  • Doctor of Philosophy of Physical Sciences, Australian National University
  • Life Fellow, American Physical Society, American Physical Society
  • Fellow, Australian Academy of Science, Australian Academy of Science
  • Member, Australian Institute of Physics, Australian Institute of Physics
  • Member, Institute of Physics, Institute of Physics
  • Life Fellow, Optica, Optica
  • Member, The Australian Optical Society, The Australian Optical Society

Research interests

  • 2022–2026 Energy-efficient artificial intelligence using quantum technologies

    Artificial intelligence (AI) is transforming society but standard technologies come with significant hidden costs: training even a single, common, learning model can emit 5 times more carbon dioxide than the lifetime emissions of the average car. This Fellowship aims to develop artificial intelligence platforms using Australia’s significant investment in quantum technologies to bypass traditional approaches to AI. The expected outcomes are neuromorphic computers that operate efficiently—with low-energy cost—and rapidly—achieving speeds impossible with conventional electronic approaches. The anticipated benefits are transformative technologies for AI, new applications across society, and new tools for exploring brain function and cognition.

  • 2018–2025 Centre for Engineered Quantum Systems (EQUS)

    The ARC Centre of Excellence for Engineered Quantum Systems, EQuS2, will build sophisticated quantum machines to harness the quantum world for practical applications. Our Centre will pioneer the designer quantum materials, quantum engines, and quantum imaging systems at the heart of these machines. We will solve the most challenging research problems at the interface of basic quantum physics and engineering, and work with partners in industry to translate these research discoveries into practical applications and devices. Our capacity- building programs will train a new generation of scientists in cutting-edge fundamental research, innovation, and entrepreneurialism, and ultimately have a major impact on Australia’s high-tech economy.

  • 2014–2017 The causal power of information in a quantum world

    The scientific method is grounded on the concept of causation and intelligent agency. In this project, we will give a philosophically coherent, theoretically justified and experimentally validated defence of the thesis that to be a cause, information must be embodied. The project will address big questions including: Does information have causal power? How does one understand causal relations in a quantum world? Are there new quantum architectures for control, based on automated intelligent agents (IA) with access to the full power of quantum information processing? The concept of information as causal has received little attention in the philosophical literature on causation. Given the advances in quantum information, it is well time this topic was explored in detail. One of the unique features of this proposal is the real time interaction between philosophers and theoretical and experimental physicists.

  • 2011–2017 Centre for Engineered Quantum Systems (EQuS)

    The future of technology lies in controlling the quantum world. The ARC Centre of Excellence for Engineered Quantum Systems (EQuS) will deliver the building blocks of future quantum technologies and, critically, ensure Australian primacy in this endeavour. Three strategic research programs will target Quantum Measurement and Control; Synthetic Quantum Systems and Simulation; and Quantum-Enabled Sensors and Metrology. Within these programs, our Centre will exploit the deepest principles and resources of quantum physics to solve specific problems in engineering, chemistry biology and medicine, stimulating the Australian scientific and engineering communities to exploit (and benefit from) transformative quantum devices.

  • 2011–2017 Centre for Quantum Computation and Communication Technology (CQC2T)

    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 physics.

  • 2008–2010 Biomolecular optoelectronic materials and devices

    The melanins are the molecules in our skin, eyes and hair that provide colour and protection from the sun. In addition to being important bio-molecules, they have properties which make them useful for high tech applications especially in electronics and optoelectronics. Unfortunately, our current understanding of these fascinating materials is poor. In our project we aim to solve this limiting problem. We will develop new science to explain their behaviour, and use this knowledge to create bio-compatible hi-tech materials and devices. We anticipate significant benefits from the perspectives of basic science and utilisation of biomaterials for new green technologies.

  • 2006–2011 Integrated quantum photonics

    The key physical technological advances of this century will be due to quantum technologies which exploit the unique properties of entanglement, a phenomenon with no everyday analogue. Understanding and applying entanglement is one of the great challenges in Physics, as is finding an experimental path to large-scale devices. This Fellowship will launch a major new initiative to address these challenges by developing optical quantum technology that integrates many photons to form powerful quantum devices. This exploits the key recent demonstration of few-particle entangling devices. By providing a route for industrialisation, this project will extend Australia’s early lead in quantum technology so as to maximise the benefits to Australia.

  • 2005–2009 Quantum Computing Concept Maturation for Optical Quantum Computing

    One of the earliest proposals for implementing quantum computation was based on encoding qubits in optical modes, each containing exactly one photon. However it is extremely difficult to couple optical modes containing very few photons. Knill , Laflamme and Milburn (KLM) have proposed a way to circumvent this restriction and implement efficient quantum computation using only passive linear optics, photodetectors, and single photon sources. This efficient optical quantum computing is distinct from all other linear optical schemes which are not efficiently scalable. The objective of this project is to produce a prototype two qubit gate for photons using linear optics, and to develop a blue-print for a multiple qubit device that might be implemented over a longer time scale.proposed an efficient linear optical quantum computing distinct from all other linear optical schemes which are not efficiently scalable. The objective of this project is to produce a prototype two qubit gate for photons using linear optics, and to develop a blueprint for a multiple qubit device that might be implemented over a longer time scale.

  • 2005–2007 Controlling Quantum Technologies

    We are on the verge of a Quantum Technology revolution, where quantum physics is driving otherwise impossible technological advances. To date, quantum technologies have made little use of the monitoring and feedback that is ubiquitous in everyday industry, keeping planes in the air and robots welding accurately. This project is concerned with learning to actively control finite-size quantum systems and processes, by studying the control of photons - single particles of light. Our experimental and theoretical research will advance the new science of quantum control and have immediate application to quantum technologies such as absolutely secure communication and ultrahigh precision measurement.

  • 2003–2008 Multidisciplinary University Research Initiative for Photonic quantum information systems

    It is now generally realized that the exploitation of fundamentally quantum-mechanical phenomena can enable significant, and in some cases, tremendous, improvement for a variety of tasks important to emergent technologies. Building on decades of successes in the experimental demonstration of such fundamental phenomena, it is not surprising that photonics is playing a preeminent role in this nascent endeavor. Many of the objectives of quantum technologies are inherently suited to optics (e.g., communications, metrology), while others may have a strong optical component (e.g., distributed quantum computing, quantum repeaters). In order for quantum information technology to attain its full potential, instrumentation by which quantum systems may be created, stored, manipulated and characterized must be developed. We propose a multi-institutional project aimed at the development of the technological tools to further the realization of quantum information processing in the optical domain. Specifically, we will investigate the following instrumentation technologies: on-demand and periodic single-photon and entangled-photon sources; high-efficiency detectors that can discriminate incident photon number; tunable sources of arbitrary entangled states and the means to characterize them via state tomography; optical quantum memories and repeaters; and the possibility of full Bell-state analysis. We propose material systems, designs, and techniques that will enable us to perform these essential functions at wavelengths ranging from ultraviolet to infrared. In addition, our approach allows coupling of generated photons into optical fibers at high data rates (presently at 76 MHz and potentially higher than 10 GHz), and combining of individual components into integrated quantum information systems.

  • 2005 Quantum Holography: encoding quantum information in optical patterns

    Quantum information applies concepts from quantum mechanics to information tasks such as communication and computation. The fundamental units of quantum information are multi-level quantum systems known as qudits � to date, most experiments have realised only their simplest two-level incarnation, the qubit. In principle, tasks such as quantum cryptography, secret sharing, and dense coding, all benefit from using qudits larger than the qubit. We propose a scheme to realise qudits in practice by encoding them into optical patterns (the transverse spatial modes of the field); to manipulate these qudits via holographic techniques; and to make entangling gates using linear optics and measurement. We will explore a range of quantum phenomena and information protocols that are only accessible with qudits.

  • 2003–2010 Centre For Quantum Computer Technology

    Development of a quantum computer (QC) for massively parallel computing is one of the major challenges in science and engineering this century. Since 200 the Centre has achieved two major breakthroughs in this field: constructing the key functional element of a silicon solid-state QC; and co-inventing a scheme for efficient linear optics QC. The proposed CoE aims to align these two nationally co-ordinated research programs with the world's existing computer and IT industries to realise a fault-tolerant multiple qubit quantum processor with integrated control, and qubit chips, and develop a scaleable optical quantum processor providing significant economic benefits to Australia.

  • 2001–2003 Optical Quantum State Engineering

    Production of non-classically correlated quantum states - entangled states - is now an issue of urgent practical importance. Communication using such states can achieve outcomes impossible with classical systems, such as absolutely secure messaging. We are interested in optically engineering arbitrary quantum states via novel twin-photon sources, and analysing these states via quantum tomography.

  • 2001–2003 Experimental implementation of efficient linear optics quantum computation

    Over the last decade physicists and computer scientists have discovered that processing information using physical devices, governed by quantum mechanics, will enable an exponential increase in computational efficiency for a given set of physical resources. Many physical systems are under investigation. Our proposal seeks to implement quantum computation in electro-optic linear networks, an approach which is efficiently scalable and compatible with existing and future optical communication technologies. The objective of this research is to produce, in three years, a prototype two qubit gate for photons using the linear optics quantum computation scheme of Knill Laflamme and Milburn (KLM), and to develop a blue-print for a multi qubit device that might be implemented over a longer time scale. One of the earliest proposals for implementing quantum computation was based on encoding each qubit in two optical modes, each containing exactly one photon. However it is extremely difficult to unitarily couple two optical modes containing few photons. Knill, Laflamme and Milburn (KLM) found a way to implement efficient quantum computation using only passive linear optics, photodetectors, and single photon sources. This efficient linear optical quantum computing (ELOQC) is distinct from all other previous linear optical schemes which are not efficiently scalable.The prototype will be approached over three years.

  • 2001–2002 Centre For Quantum Computer Technology

    The Centre for Quantum Computer Technology will carry out a broad range of experimental and theoretical research programs that will lead to construction, at the atomic level, of a revolutionary prototype solid state quantum computer (SSQC) in silicon. The SSQC proposal and detailed fabrication strategy developed at UNSW has received significant international attention and review by experts in the field and is widely regarded as the one most likely to lead to a QC that can be scaled to the number of quantum bits (qubits) necessary for practical applications. The ability of a quantum computer to carry out calculations at the atomic level by manipulation of superpositions of quantum states is expected to provide massive parallel processing leading to unprecedented computing power in applications of commercial and national significance. The Centre will enable Australia to play a central role in the development of 21st century computer technology.

  • 1997–1999 High-efficiency Quantum Interrogation

    (Also known as "interaction-free" measurement). Using the complementary wave- and particle-like natures of photons, the basic particles of light, it is possible to make measurements where the presence of an object can be unambiguously determined without the photons ever interacting with the object. Previous detectors have achieved this with efficiencies of < 80%. In this project we aim to develop a high-efficiency IFM detector, one with efficiencies of 90% or better. Such a detector has great potential for imaging delicate objects, such as biological cells, or quantum systems. An old, but still illuminating, discussion of such measurements can be found here.

Search Professor Andrew White’s works on UQ eSpace

230 works between 1991 and 2024
All (230) Journal Article (130) Book Chapter (5) Conference Publication (81) Other Outputs (14)

61 - 80 of 230 works

Featured

1999

Journal Article

High-Efficiency Quantum Interrogation Measurements via the

Kwiat, P. G., White, A. G., Mitchell, J. R., Nairz, O., Weihs, G., Weinfurter, H. and Zeilinger, A. (1999). High-Efficiency Quantum Interrogation Measurements via the. Physical Review Letters, 83 (23), 4725-4728. doi: 10.1103/PhysRevLett.83.4725

High-Efficiency Quantum Interrogation Measurements via the

Featured

1998

Journal Article

‘‘Interaction-free’’ imaging

White, Andrew G., Mitchell, Jay R., Nairz, Olaf and Kwiat, Paul G. (1998). ‘‘Interaction-free’’ imaging. Physical Review A, 58 (1), 605-608. doi: 10.1103/PhysRevA.58.605

‘‘Interaction-free’’ imaging

Featured

1998

Journal Article

"Interaction-free" imaging

White, Andrew G., Mitchell, Jay R., Nairz, Olaf and Kwiat, Paul G. (1998). "Interaction-free" imaging. Physical Review a, 58 (1), 605-613. doi: 10.1103/PhysRevA.58.605

"Interaction-free" imaging

Featured

1998

Journal Article

The Los Alamos trapped ion quantum computer experiment

Hughes, RJ, James, DFV, Gomez, JJ, Gulley, MS, Holzscheiter, MH, Kwiat, PG, Lamoreaux, SK, Peterson, CG, Sandberg, VD, Schauer, MM, Simmons, CM, Thorburn, CE, Tupa, D, Wang, PZ and White, AG (1998). The Los Alamos trapped ion quantum computer experiment. Fortschritte der Physik-Progress of Physics, 46 (4-5), 329-361. doi: 10.1002/(SICI)1521-3978(199806)46:4/53.0.CO;2-X

The Los Alamos trapped ion quantum computer experiment

Featured

1997

Journal Article

Classical and quantum signatures of competing chi((2)) nonlinearities

White, A. G., Lam, P. K., Taubman, M. S., Marte, M. A. M., Schiller, S., McClelland, D. E. and Bachor, H. A. (1997). Classical and quantum signatures of competing chi((2)) nonlinearities. Physical Review A, 55 (6), 4511-4515. doi: 10.1103/PhysRevA.55.4511

Classical and quantum signatures of competing chi((2)) nonlinearities

Featured

1997

Journal Article

Classical and quantum properties of the subharmonic-pumped parametric oscillator

Schiller, Stephan, Bruckmeier, Robert and White, Andrew G. (1997). Classical and quantum properties of the subharmonic-pumped parametric oscillator. Optics Communications, 138 (1-3), 158-171. doi: 10.1016/S0030-4018(96)00793-6

Classical and quantum properties of the subharmonic-pumped parametric oscillator

Featured

1997

Journal Article

Noiseless amplification in cavity-based optical systems with an internal two-photon process .2. Self-frequency-doubling laser and second-harmonic generation, self-down-converting laser - Comment

White, AG, Ralph, TC and Bachor, HA (1997). Noiseless amplification in cavity-based optical systems with an internal two-photon process .2. Self-frequency-doubling laser and second-harmonic generation, self-down-converting laser - Comment. Journal of Modern Optics, 44 (3), 651-652. doi: 10.1080/09500349708232928

Noiseless amplification in cavity-based optical systems with an internal two-photon process .2. Self-frequency-doubling laser and second-harmonic generation, self-down-converting laser - Comment

Featured

1996

Journal Article

Experimental test of modular noise propagation theory for quantum optics

White, Andrew G., Taubman, Matthew S., Ralph, Timothy C., Lam, Ping Koy, McClelland, David E. and Bachor, Hans-A. (1996). Experimental test of modular noise propagation theory for quantum optics. Physical Review a, 54 (4), 3400-3404. doi: 10.1103/PhysRevA.54.3400

Experimental test of modular noise propagation theory for quantum optics

Featured

1996

Journal Article

Cascaded second-order nonlinearity in an optical cavity

White, A. G., Mlynek, J. and Schiller, S. (1996). Cascaded second-order nonlinearity in an optical cavity. Europhysics Letters, 35 (6), 425-430. doi: 10.1209/epl/i1996-00131-8

Cascaded second-order nonlinearity in an optical cavity

Featured

1996

Journal Article

Active versus passive squeezing by second-harmonic generation

White, AG, Ralph, TC and Bachor, HA (1996). Active versus passive squeezing by second-harmonic generation. Journal of the Optical Society of America B-Optical Physics, 13 (7), 1337-1346. doi: 10.1364/JOSAB.13.001337

Active versus passive squeezing by second-harmonic generation

Featured

1995

Journal Article

Squeezed-Light From 2nd-Harmonic Generation - Experiment Versus Theory

Ralph, TC, Taubman, MS, White, AG, McClelland, DE and Bachor, HA (1995). Squeezed-Light From 2nd-Harmonic Generation - Experiment Versus Theory. Optics Letters, 20 (11), 1316-1318. doi: 10.1364/OL.20.001316

Squeezed-Light From 2nd-Harmonic Generation - Experiment Versus Theory

Featured

1995

Journal Article

Retrieving Squeezing From Classically Noisy Light in 2nd-Harmonic Generation

Ralph, TC and White, AG (1995). Retrieving Squeezing From Classically Noisy Light in 2nd-Harmonic Generation. Journal of the Optical Society of America B-Optical Physics, 12 (5), 833-839. doi: 10.1364/JOSAB.12.000833

Retrieving Squeezing From Classically Noisy Light in 2nd-Harmonic Generation

Featured

1992

Journal Article

Generation of Optical-Phase Singularities by Computer-Generated Holograms

Heckenberg, NR, McDuff, R, Smith, CP and White, AG (1992). Generation of Optical-Phase Singularities by Computer-Generated Holograms. Optics Letters, 17 (3), 221-223. doi: 10.1364/OL.17.000221

Generation of Optical-Phase Singularities by Computer-Generated Holograms

Featured

1991

Journal Article

Interferometric Measurements of Phase Singularities in the Output of a Visible Laser

White, AG, Smith, CP, Heckenberg, NR, Rubinszteindunlop, H, McDuff, R, Weiss, CO and Tamm, C (1991). Interferometric Measurements of Phase Singularities in the Output of a Visible Laser. Journal of Modern Optics, 38 (12), 2531-2541. doi: 10.1080/09500349114552651

Interferometric Measurements of Phase Singularities in the Output of a Visible Laser

Featured

1991

Journal Article

Gyromagnetic Ratios of Low-Lying Rotational States in Gd-156, Gd-158, Gd-160

Stuchbery, AE, White, AG, Dracoulis, GD, Schiffer, KJ and Fabricius, B (1991). Gyromagnetic Ratios of Low-Lying Rotational States in Gd-156, Gd-158, Gd-160. Zeitschrift Fur Physik A-Hadrons and Nuclei, 338 (2), 135-138. doi: 10.1007/BF01284786

Gyromagnetic Ratios of Low-Lying Rotational States in Gd-156, Gd-158, Gd-160

2024

Journal Article

Highly efficient storage of cavity SPDC single photons in room temperature gradient echo memory

Leung, Anthony C., Lau, W. Y. Sarah, Tranter, Aaron D., Paul, Karun V., Rambach, Markus, Buchler, Ben C., Lam, Ping Koy, White, Andrew G. and Weinhold, Till J. (2024). Highly efficient storage of cavity SPDC single photons in room temperature gradient echo memory. APL Quantum, 1 (3). doi: 10.1063/5.0207712

Highly efficient storage of cavity SPDC single photons in room temperature gradient echo memory

2024

Journal Article

Precisely determining photon-number in real time

Assis Morais, Leonardo, Weinhold, Till, Pereira de Almeida, Marcelo, Combes, Joshua, Rambach, Markus, Lita, Adriana, Gerrits, Thomas, Nam, Sae Woo, White, Andrew G. and Gillett, Geoff (2024). Precisely determining photon-number in real time. Quantum, 8, 1-16. doi: 10.22331/q-2024-05-23-1355

Precisely determining photon-number in real time

2024

Conference Publication

Measuring impossible parameters with indefinite causal order

McKinlay, Jaden, Rambach, Markus, Goldberg, Aaron Z., Heshami, Khabat, Sánchez-Soto, Luis and White, Andrew G. (2024). Measuring impossible parameters with indefinite causal order. CLEO: Fundamental Science 2024, Charlotte, NC, United States, 5–10 May 2024. Washington, DC, United States: Optical Society of America. doi: 10.1364/CLEO_FS.2024.FM4K.2

Measuring impossible parameters with indefinite causal order

2023

Journal Article

The insufficient word in Physics Today’s first issue

White, Andrew G. (2023). The insufficient word in Physics Today’s first issue. Physics Today, 76 (12), 11-12. doi: 10.1063/PT.3.5352

The insufficient word in Physics Today’s first issue

2023

Conference Publication

Educating decision makers on resource allocations for quantum technologies

Manfield, Russell, Harvey, Michael and White, Andrew (2023). Educating decision makers on resource allocations for quantum technologies. Seventeenth Conference on Education and Training in Optics and Photonics: ETOP 2023, Cocoa Beach, FL, United States, 15-18 May 2023. Bellingham, WA, United States: SPIE. doi: 10.1117/12.2668765

Educating decision makers on resource allocations for quantum technologies

Current funding

  • 2024 - 2027
    National Quantum Computing Testbed Facility
    Quantum and Advanced Technologies Commercialisation Infrastructure Program
    Open grant
  • 2022 - 2025
    Quantum-enhanced atomic gravimetry for improved sensing capabilities (AISRF led by ANU)
    Australian National University
    Open grant
  • 2022 - 2027
    Energy-efficient artificial intelligence using quantum technologies
    ARC Australian Laureate Fellowships
    Open grant
  • 2018 - 2025
    ARC Centre of Excellence for Engineered Quantum Systems (EQuS2)
    ARC Centres of Excellence
    Open grant

Past funding

  • 2020 - 2021
    [Quantum Accelerator] Efficient Fast Photonic Integrated Circuits for Photonic Quantum Computing
    United States Air Force Office of Scientific Research
    Open grant
  • 2019
    Multimode optical waveguide characterisation facility
    UQ Major Equipment and Infrastructure
    Open grant
  • 2018
    Imaging in the nano-scale age: terahertz and millimetre wave microanalysis
    UQ Major Equipment and Infrastructure
    Open grant
  • 2015 - 2019
    Disruptive information technology: putting the photon into photonics
    Vice-Chancellor's Research and Teaching Fellowship
    Open grant
  • 2015 - 2016
    Advanced Superfluid Physics Facility
    UQ Major Equipment and Infrastructure
    Open grant
  • 2014
    Facility for fabrication and characterisation of micro/nano-optoelectronic devices
    UQ Major Equipment and Infrastructure
    Open grant
  • 2014 - 2017
    The causal power of information in a quantum world
    Templeton World Charity Foundation
    Open grant
  • 2013 - 2016
    Computational complexity of bosons in linear networks.
    United States Asian Office of Aerospace Research and Development
    Open grant
  • 2013
    UQ Travel Awards Category 1 - Professor Daniel James
    UQ Travel Grants Scheme
    Open grant
  • 2011 - 2018
    ARC Centre of Excellence for Quantum Computation and Communication Technology (ARC COE administered by the University of New South Wales)
    University of New South Wales
    Open grant
  • 2011 - 2017
    ARC Centre of Excellence for Engineered Quantum Systems (EQuS)
    ARC Centres of Excellence
    Open grant
  • 2011 - 2014
    Simulating quantum systems in biology, chemistry and physics
    Vice-Chancellor's Senior Research Fellowship
    Open grant
  • 2010 - 2011
    Ultra-precision cutting and polishing machines for fabricating high-Q crystalline resonators (ARC LIEF administered by ANU)
    ARC LIEF Collaborating/Partner Organisation Contributions
    Open grant
  • 2008 - 2011
    Biomolecular optoelectronic materials and devices
    ARC Discovery Projects
    Open grant
  • 2007
    Detectors and sources for photonic quantum engineering
    ARC Linkage International
    Open grant
  • 2006 - 2011
    Integrated quantum photonics
    ARC Federation Fellowships
    Open grant
  • 2006
    Foundational National Nanotechnology Infrastructure
    ARC LIEF Collaborating/Partner Organisation Contributions
    Open grant
  • 2006 - 2010
    Optical Quantum Computing
    Department of Innovation, Industry, Science and Research
    Open grant
  • 2005 - 2010
    Optical Quantum Computing (University of Illinois)
    University of Illinois
    Open grant
  • 2005 - 2007
    Controlling quantum technologies
    ARC Discovery Projects
    Open grant
  • 2004 - 2005
    Quantum Holography: encoding quantum information in optical patterns
    UQ Foundation Research Excellence Awards - DVC(R) Funding
    Open grant
  • 2003 - 2008
    Photonic quantum information systems
    Stanford University
    Open grant
  • 2003 - 2010
    ARC Centre of Excellence for Quantum Computer Technology (UNSW lead institution)
    ARC Centres of Excellence
    Open grant
  • 2001 - 2004
    Experimental Implementation of Efficient Linear Optics Quantum Computation
    United States Army Research Office
    Open grant
  • 2001 - 2003
    Optical Quantum State Engineering.
    ARC Australian Research Council (Large grants)
    Open grant
  • 2000
    Optical entangler for Quantum Communication
    Australian National University
    Open grant
  • 2000
    A Single Photon Source Using a Surface Acoustic Wave in Nanofabricated Semiconductors.
    ARC Australian Research Council (Small grants)
    Open grant
  • 2000
    High Efficiency Interaction-free Detectors.
    ARC Australian Research Council (Small grants)
    Open grant
  • 2000
    Special Research Centre for Quantum Computer Technology
    University of New South Wales
    Open grant

Availability

Professor Andrew White is:
Available for supervision

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Available projects

Supervision history

Current supervision

Completed supervision

Enquiries

Contact Professor Andrew White directly for media enquiries about:

  • Biophotonics
  • Biophysics
  • Computing - quantum
  • Holography
  • Light - physics
  • Light polarisation
  • Mechanics - quantum
  • Media and Physics
  • Optics
  • Optics - quantum
  • Photons - physics
  • Physical sciences
  • Physics - light
  • Physics - photons
  • Physics - quantum
  • Polarisaion - light
  • Quantum computing
  • Quantum information
  • Quantum mechanics
  • Quantum metrology
  • Quantum optics
  • Quantum phenomena
  • Quantum physics
  • Quantum technology
  • Technology - quantum

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