Potential student research projects

The Research School of Physics performs research at the cutting edge of a wide range of disciplines.

By undertaking your own research project at ANU you could open up an exciting career in science.

Filter projects

Some other physics related research projects may be found at the ANU College of Engineering & Computer Science, the Mathematical Sciences Institute and the Research School of Astronomy & Astrophysics

Astrophysics

Positron Annihilation Spectroscopy

Understanding material defects at the atomic scale using anitmatter.

Dr Joshua Machacek, Professor Stephen Buckman

Mid-infrared single-mode waveguides for the LIFE space mission

The Large Interferometer for Exoplanets (LIFE) aims to detect biosignatures on Earth-like planets by collecting mid-infrared spectra. A major challenge is creating low-loss waveguides for spatial filtering. This project explores photonic crystal waveguides, using femtosecond lasers and Bessel beams to fabricate microstructures in transparent crystals for efficient light guidance.

Dr Ludovic Rapp, Dr Shan Liu

Calibrate gravitational wave detectors

For gravitational-wave detections and analyses, the raw outputs from the gravitational-wave detectors need to be converted into analysable data through some calibration apparatus. This project investigates new techniques to improve calibration accuracy and precision and better integrate the calibration bias into astrophysical analyses. 

Dr Lilli (Ling) Sun, A/Prof Bram Slagmolen, Distinguished Prof Susan Scott

Gravitational waves from ultralight boson clouds around black holes

Ultralight boson particles have been predicted to solve problems in particle and high-energy physics and are compelling dark matter candidates. We develop algorithms and search for these conjectured ultralight bosons around black holes via gravitational-wave observations. 

Dr Lilli (Ling) Sun, Distinguished Prof Susan Scott, Dr Karl Wette

Neutron stars: understanding physics at the extreme

Neutron stars are a unique laboratory for probing physics under the greatest extremes of density and gravity, far beyond what is capable in terrestrial laboratories.  This project aims to use gravitational wave discoveries and electromagnetic observations of neutron stars to examine fundamental physics.

Dr Karl Wette, Distinguished Prof Susan Scott

Ultra-sensitive radon detection for rare-event physics experiments

Radioactivity from radon is a leading background for dark matter and other rare-event physics experiments. Developing ultra-sensitive radon detection is crucial to improve discovery potential and enable the next generation of breakthroughs in fundamental physics.

Dr Robert Renz Marcelo Gregorio, Dr Lindsey Bignell, Professor Gregory Lane

The intersection of nuclear structure and nuclear scattering

This project explores nuclear scattering using shell-model-derived potentials to better understand complex nuclear interactions. Students will enhance coding skills, deepen quantum mechanics knowledge, and apply high-performance computing to study processes relevant to nuclear astrophysics and nucleosynthesis, shedding light on the origins of the chemical elements. 

Professor Cedric Simenel

Exotic nuclear structure towards the neutron dripline

Investigate the structure and radioactive-decay properties of exotic nuclei, and the roles they play in advancing modern nuclear theory, stella nucleosynthesis and applications of nuclear technology in society. 

Dr AJ Mitchell, Professor Gregory Lane

Radon control in directional dark matter detectors

Directional dark matter searches provide a way to probe beyond the irreducible ‘neutrino fog’ that limits traditional dark matter experiments. CYGNUS-OZ is part of the global directional dark matter effort, and this project focuses on the critical challenge of radon control in these detectors.

Dr Robert Renz Marcelo Gregorio, Dr Lindsey Bignell, Professor Gregory Lane

Radioimpurities in particle detectors for dark matter studies

This experiment will characterise dark matter detector material. Lowest levels of natural radioactivity in high purity samples will be analysed via ultra-senstive single atom counting using acclerator mass spectrometry.

Dr Michaela Froehlich , Dr Yiyi Zhong, Dr Zuzana Slavkovska, A/Prof Stephen Tims

Continuous gravitational waves: new methods for new discoveries

The next big discovery in gravitational wave astronomy may be a first detection of continuous gravitational waves from rapidly-spinning neutron stars. This projects aims to develop the data analysis methods needed for such a discovery.

Dr Karl Wette, Distinguished Prof Susan Scott

Advanced detector development for rare event particle physics

Experimental, simulation, and data analysis projects are available to help develop advanced detection technology which will form the basis of a future large particle physics experiment in Australia

Dr Lindsey Bignell, Dr Robert Renz Marcelo Gregorio, Miss Victoria Bashu, Professor Gregory Lane

Prospects of future ground-based gravitational-wave detector network

In this project, we study the gravitational-wave astronomy and astrophysics science cases and observational prospects with future ground-based gravitational-wave observatories.

Dr Lilli (Ling) Sun, A/Prof Bram Slagmolen, Distinguished Prof David McClelland

How does a black hole ring?

We study the numerical waveforms for the gravitational waves emitted during the black hole ringdown stage, implement tools and data analysis frameworks, and analyze the latest gravitational-wave data to estimate black hole properties and test the general theory of relativity.

Dr Lilli (Ling) Sun, Distinguished Prof Susan Scott

When two neutron stars collide, what is left behind?

In 2017, the first discovery of gravitational waves from two colliding neutron stars heralded a new age of multi-messenger astronomy. But what was left over after the collision? This project aims to find out.

Dr Karl Wette, Distinguished Prof Susan Scott

Multi-messenger gravitational-wave astronomy

The event of two merging neutron stars, GW170817, was observed in gravitational waves and across the electromagnetic spectrum, opening a new era of multi-messenger astronomy. We work on following up electromagnetic counterparts to future detections of gravitational waves and are ready to contribute to the new science of multi-messenger astronomy. 

Distinguished Prof Susan Scott, Dr Lilli (Ling) Sun, Dr Karl Wette

Unveiling galaxy formation and black hole growth through ultra-low frequency gravitational waves

This project aims to build a novel framework to study supermassive black holes via their unique gravitational wave signatures, providing a multi-messenger tool to constrain galaxy formation in the early universe.
This is a joint project between CGA/RSPhys and RSAA. Co-supervisor at RSAA: Dr Yuxiang Qin (yuxiang.qin@anu.edu.au)  

Dr Lilli (Ling) Sun

Simulating cosmic-ray interactions with materials for dark matter searching and commercial applications

This project uses Geant4 simulations to investigate how naturally occurring cosmic rays interact with materials relevant to physics and environmental research, including NaI(Tl) crystals, gaseous detectors, and soil.

Dr Yiyi Zhong, Dr Lindsey Bignell

Atomic and Molecular Physics

Positron Annihilation Spectroscopy

Understanding material defects at the atomic scale using anitmatter.

Dr Joshua Machacek, Professor Stephen Buckman

Mass-entangled ultracold helium atoms

This experimental project aims to create entangled states of ultracold helium atoms where the entanglement is between atoms of different mass. By manipulating the entangled pairs using laser induced Bragg transitions and measuring the resulting correlations, we will study how gravity affects mass-entangled particles.

Dr Sean Hodgman, Professor Andrew Truscott

Shining new light on the ‘proton radius puzzle’ using ultracold helium

This experimental project, involves building an ultra-stable frequency laser which will be used to probe electronic transitions in ultracold - 3He and 4He.  These measurements will then be used to determine the differential isotopic nuclear charge radius of helium to a world leading absolute accuracy.

Professor Andrew Truscott, Dr Sean Hodgman

Atomic magnetometer for exploring physics beyond the standard model and gyroscopy

Atomic sensors are exquisitely sensitive. We aim to model and build a new generation of atomic sensors to measure magnetic fields, rotation and dark matter. 

Professor Ben Buchler

Positron interactions with structured surfaces

We are investigating novel effects and applications using positrons and structured surfaces.

Dr Joshua Machacek, Dr Sergey Kruk

Atom-light interactions in quantum memories

Quantum memories store light in atomic ensembles for applications in quantum computing and networking. This project explores how atoms and light interact in prototype quantum memories that use rare earth atoms in crystals for storage, aiming to improve memory efficiency,  storage capacity, and performance in real-world devices.

Dr Rose Ahlefeldt, Dr James Stuart

Interactions between antimatter and ultracold atoms

Antiparticles and antimatter have progressed from theory and science fiction to become an important and exciting area of pure and applied science. This fundamental atomic physics project will investigate how antimatter and matter interact by experimentally studying the interaction of positrons (the electron anti-particle) with trapped ultracold rubidium atoms.

Dr Sean Hodgman, Professor Stephen Buckman, Dr Joshua Machacek

Exploring the many body physics in an atomic matterwave system with PT symmetry

Investigating the possible enhancement of sensitivity in atomic sensors with PT symmetry and the underlying many body evolution.

Dr Jessica Eastman, Dr Simon Haine

Biophysics

Positron Annihilation Spectroscopy

Understanding material defects at the atomic scale using anitmatter.

Dr Joshua Machacek, Professor Stephen Buckman

Solid-state nanopore sensors: Unveiling new frontiers in biomolecule detection

Investigate novel nanopore bio-sensors using nanofabrication, bio-chemsity and machine learning.

Prof Patrick Kluth

Understanding drought-resistance in Australian plants with 3D X-ray microscopy

This project will use unique, ANU-designed 3D X-ray microscopes and state-of-the art image analysis to track physiological responses of drought-tolerant Australian plants when subjected to water stress. The results will help us understand the mechanisms that underpin drought-tolerance, helping resolve ongoing debates and helping understand which forest eco-systems that are most vulnerable to climate change, and why.

Prof Adrian Sheppard, Dr Levi Beeching, Dr Andrew Kingston

Femtosecond laser for ultra-precise cavity drilling in modern dentistry

Development of efficient, versatile and fast laser femtosecond processes for advanced applications in modern dentistry promising a precise pain-free dental treatment for all patients.

Dr Ludovic Rapp

Clean Energy

Flexible, cost-effective III-V semiconductor-perovskite tandem solar cells

This project aims to develop high efficiency, cost-effective III-V semiconductor-perovskite tandem solar cells which are flexible and lightweight, while achieving excellent device stability.

Professor Hoe Tan, Dr Tuomas Haggren, Professor Chennupati Jagadish

Machine learning approaches for nuclear fusion reactions

Proton-boron fusion has the potential to deliver limitless clean energy. This project will aims to understand the physics underpinng this important nuclear reaction by developing machine learning approaches to analyse complex reaction probabilities.

Dr Edward Simpson

Engineering in Physics

Developing ultra-high resolution optical meta-surface sensors

The project aims to develop methods to improve the sensitivity of optical metasurfaces for the detection of chemical and biological markers. By tailoring a high-precision optical interferometric sensing solution to the optical properties of a metasurface under-test, the project will improve the sensitivity of these devices, developing a new range of targeted ultra-precise metasurface sensors.

Dr Chathura Bandutunga , Prof Dragomir Neshev

Machine learning for optics and controls

Optical cavities are widely used in physics and precision measurement.  This project will explore the use of modern machine learning methods for the control of suspended optical cavities.

A/Prof Bram Slagmolen, Dr Jiayi Qin, Professor Robert Ward

Positron Annihilation Spectroscopy

Understanding material defects at the atomic scale using anitmatter.

Dr Joshua Machacek, Professor Stephen Buckman

Calibrate gravitational wave detectors

For gravitational-wave detections and analyses, the raw outputs from the gravitational-wave detectors need to be converted into analysable data through some calibration apparatus. This project investigates new techniques to improve calibration accuracy and precision and better integrate the calibration bias into astrophysical analyses. 

Dr Lilli (Ling) Sun, A/Prof Bram Slagmolen, Distinguished Prof Susan Scott

Exploring physics with neural networks

Machine learning based on deep neural networks is a powerful method for improving the performance of experiments.  It may also be useful for finding new physics.

Dr Aaron Tranter, Professor Ben Buchler, Professor Ping Koy Lam

Ultra-sensitive radon detection for rare-event physics experiments

Radioactivity from radon is a leading background for dark matter and other rare-event physics experiments. Developing ultra-sensitive radon detection is crucial to improve discovery potential and enable the next generation of breakthroughs in fundamental physics.

Dr Robert Renz Marcelo Gregorio, Dr Lindsey Bignell, Professor Gregory Lane

High pressure creation of new forms of diamond

The hexagonal form of sp3 bonded carbon is predicted to be harder than 'normal' cubic diamond. We can make tiny amounts of this new form of diamond and want to know if it really is harder than diamond.

Prof Jodie Bradby, Dr Xingshuo Huang

Creation of novel hybrid boron nitride materials

This project focussed on the creation of novel hybrid boron nitride materials by utilizing advanced green techniques of mechanochemistry and high-pressure methods. 

Prof Jodie Bradby, Dr Xingshuo Huang

Nuclear structure studies with particle transfer reactions

This project will use nuclear reactions to study the basic make-up of atomic nuclei at the quantum level, and investigate the impact of nuclear structure on sub-atomic forces and fundamental physics. 

Dr AJ Mitchell, Professor Gregory Lane, Emeritus Professor Andrew Stuchbery

Engineering Inter-spacecraft laser links

Inter-satellite laser links are an emerging technology with applications in Earth Observation, telecommunications, security, and, the focus of the CGA space technology group.

Professor Kirk McKenzie, Dr Andrew Wade, Dr Ya Zhang, Ms Emily Rose Rees

Dual torsion pendulum for quantum noise limited sensing

Construct a small dual tosion pendulum which have their centre of mass co-incide and their rotational axis colinear. Inital diagnostics will be done using shadow sensors.

A/Prof Bram Slagmolen, Dr Sheon Chua, Professor Robert Ward

Miniature absolute gravimeter

Absolute gravimeters tie their measurement of gravity to the definition of the second 
by interrogating the position of a falling test mass using a laser interferometer. Our vision is to develop and prototype a miniaturised absolute gravimeter by 
leveraging modern vacuum, laser, and micro-electromechanical systems.

Dr Samuel Legge, Professor John Close

Vibration control for optical interferometry

Develop an active vibraiton isolation platform to provide a quiet, small displacement environment for high precision inteferometry.

A/Prof Bram Slagmolen, Dr Sheon Chua, Professor Robert Ward

Machining learning for coupled interferometer alignment and control

This project aims to develop a three-mirror coupled optical cavity system with automated alignment and control. Machine learning will be used to identify optical modes and optimize cavity operation, enabling advanced studies in precision optical control and interferometry.

Dr Jiayi Qin, A/Prof Bram Slagmolen, Professor Robert Ward

Terahertz polarisation optics

This project will pioneer compact, low-loss terahertz polarisation optics—polarisers, waveplates, and circular polarisers—by harnessing artificial birefringence in metamaterials to overcome the limitations of natural crystals.

Professor Ilya Shadrivov, Mr Oleg Kameshkov, Dr Vladlen Shvedov

Ultra-fast lifetime measurements of nuclear excited states

Use ultra-fast gamma-ray detectors to perform excited-state lifetime measurements and investigate single-particle and collective features of atomic nuclei. 

Professor Gregory Lane, Dr AJ Mitchell, Emeritus Professor Andrew Stuchbery, Emeritus Professor Tibor Kibedi

Fibre optic sensor arrays for vibrometry and acoustic sensing

By leveraging hybrid digital-optical methods, we develop new distributed and quasi-distributed fibre-optic acoustic sensors. These acoustic sensors aim to measure vibration, strain and displacement all while localising the signal source along an optical fibre.

Dr Chathura Bandutunga , A/Prof Bram Slagmolen

Employing machine learning-based methods in image processing for green iron ore

Dr Yulai Zhang, Dr Philipp Loesel, Dr Neelima Kandula, Dr Aleese Barron

Higher-order mode displacement sensors

A project to advance a prototype displacement sensor to test-type phase, via improved compact mechanical design,  vacuum compatibility, and improved sensor testing.

Dr Sheon Chua, A/Prof Bram Slagmolen

Imaging CO2 storage in coal with X-ray microCT

This project will use X-ray microCT imaging and advanced image analysis methods to investigate CO2 injection in coal, providing new insights into the potential of coal seams for CO2 storage.

Dr Yulai Zhang

Wood-based mechanical metamaterials

The field of mechanical metamaterials is a fast-developing research domain, here the project aims at studying and developping wood-based and wood-inspired metamaterials.

Associate Professor Nicolas Francois, Dr Mohammad Saadatfar, Professor Mark Knackstedt

Environmental Physics

High pressure non-equilibrium plasma discharges in chemically reactive systems

The goal of this research is to study high pressure non-equilibrium plasma discharges in chemically reactive systems with applications to space, waste treatment and material science.

A/Prof Cormac Corr

Montebello Islands - A former nuclear test site

This project investigates anthropogenic radionuclides from the 1950s–60s nuclear tests in various marine sample types near the Montebello Islands. By analysing isotopic signatures, it aims to distinguish contributions from Montebello and Pacific Proving Ground tests, supporting environmental tracing, dose assessment, and collaboration with institutions like ANSTO and ARPANSA.

Dr Michaela Froehlich , Ms Madison Williams-Hoffman

Strontium-90 in the environment

Strontium is a naturally occurring element that accumulates in bones, with its radioactive isotope Sr-90 posing environmental concerns due its presence in nature.

Dr Michaela Froehlich , Dr Stefan Pavetich, A/Prof Stephen Tims

Radioactivity in our environment

Radionuclides such as 236U and 239Pu were introduced into the environment by the atmospheric nuclear weapon tests and an be readily measured by accelerator mass spectrometry.

Dr Michaela Froehlich

Fusion and Plasma Confinement

The effect of He irradiation on the microstructure and mechanical properties of W/ W alloys

Nuclear fusion is a promising technology for solving the world’s energy crisis while drastically reducing pollution and avoiding the creation of nuclear waste, a major issue for nuclear fission. However, there are many scientific and technical challenges to be overcome before this technology can be used for large-scale energy generation. One of the problems that need to be solved is the tolerance of the diverter walls to the high temperatures and He implantation – conditions that are prevalent inside the fusion reactors.

A/Prof Cormac Corr, Dr Matt Thompson

Machine learning approaches for nuclear fusion reactions

Proton-boron fusion has the potential to deliver limitless clean energy. This project will aims to understand the physics underpinng this important nuclear reaction by developing machine learning approaches to analyse complex reaction probabilities.

Dr Edward Simpson

Diagnosing plasma-surface interactions under fusion-relevant conditions

This project involves studying the complex plasma-surface interaction region of a fusion-relevant plasma environment through laser-based and spectroscopic techniques.

A/Prof Cormac Corr, Dr Matt Thompson

Materials Science and Engineering

Flexible, cost-effective III-V semiconductor-perovskite tandem solar cells

This project aims to develop high efficiency, cost-effective III-V semiconductor-perovskite tandem solar cells which are flexible and lightweight, while achieving excellent device stability.

Professor Hoe Tan, Dr Tuomas Haggren, Professor Chennupati Jagadish

III-V nanowire arrays for ultra-sensitive, selective, and flexible gas sensing applications

This project aims at design, fabrication, and characterisation of advanced III-V semiconductor nanowire gas sensors for environmental and healthcare monitoring.

Professor Lan Fu, Dr Zhe (Rex) Li

Positron Annihilation Spectroscopy

Understanding material defects at the atomic scale using anitmatter.

Dr Joshua Machacek, Professor Stephen Buckman

Nano-scale III-V light emitters on Si

Although planar growth of III-V materials on Si has been widely demonstrated, direct growth of III-V nanostructures on Si remains challenging. This project aims to realize InP/InAsP light-emitting nanostructures on Si substrates by engineering the III-V/Si interfacial energy, enabling monolithic integration of active photonic components on silicon.

Dr Wei Wen Wong, Professor Hoe Tan, Professor Chennupati Jagadish

High pressure creation of new forms of diamond

The hexagonal form of sp3 bonded carbon is predicted to be harder than 'normal' cubic diamond. We can make tiny amounts of this new form of diamond and want to know if it really is harder than diamond.

Prof Jodie Bradby, Dr Xingshuo Huang

Creation of novel hybrid boron nitride materials

This project focussed on the creation of novel hybrid boron nitride materials by utilizing advanced green techniques of mechanochemistry and high-pressure methods. 

Prof Jodie Bradby, Dr Xingshuo Huang

Quantum chemistry modelling of rare earth crystals for quantum technologies

Quantum technology applications of rare earth crystals would benefit from accurate ab-initio models of how quantum properties arise from fundamental atom-atom interactions in crystals. In this project, we will adapt recent advances in molecular quantum chemistry models to rare earth crystals and apply them to quantum technology problems.

Dr Rose Ahlefeldt

Bottom-up, parity-time (PT) symmetric micro-cavity lasers

In this project, we aim to explore PT-symmetric lasing in III-V semiconductor micro-cavity lasers that are epitaxially grown on their substrates, free from any etching-induced damage. In particular, we aim to demonstrate performance improvements by exploiting some of the unique features of bottom-up grown laser cavities.

Dr Wei Wen Wong, Professor Hoe Tan, Professor Chennupati Jagadish

Nanowire photodetectors for photonic and quantum systems

Semiconductor nanowires are emerging nano-materials with substantial opportunities for novel photonic and quantum device applications. This project aims at developing a new generation of high performance NW based photodetectors for a wide range of applications.

Professor Lan Fu, Dr Zhe (Rex) Li, Professor Chennupati Jagadish

Positron interactions with structured surfaces

We are investigating novel effects and applications using positrons and structured surfaces.

Dr Joshua Machacek, Dr Sergey Kruk

GeSn defect properties measured by nanoindentation

To understand defects in metal-semiconductor alloys, specifically GeSn in this project, to help making better alloy films and devices.

Dr Xingshuo Huang, Prof Jodie Bradby, Emeritus Professor Jim Williams

Shape engineering of semiconductor nanostructures for novel device applications

This project aims to investigate the growth of III-V semiconductors on pre-patterned nanotemplates. By using different shapes and geometries, it is envisaged that these nanostructures will provide novel architectures for advanced, next generation optoelectronic devices.

Professor Hoe Tan, Professor Chennupati Jagadish

Bottom-up, quasi-bound states in the continuum (quasi-BIC) metasurface lasers

This project aims to demonstrate lasing in a bottom-up metasurface supporting a perturbed symmetry-protected quasi-BIC mode, while exploring its unique optical properties. We will also develop fabrication processes to achieve electrically injected lasing, highlighting the advantages of bottom-up metasurface design over conventional top-down laser fabrication approaches.

Dr Wei Wen Wong, Professor Hoe Tan, Professor Chennupati Jagadish

Functional nanopore membranes

Nano-pore membranes have important applications in chemical- and bio-sensing, water filtration and protein separation. This project will investigate our innovative technology to fabricate nanopore membranes in silicon dioxide and silicon nitride and exploit their use for advanced applications.

Prof Patrick Kluth

Electrically-injected bottom-up III-V micro-cavity lasers

Bottom-up fabrication of lasers via epitaxial growth is emerging as a promising alternative to conventional top-down methods, offering potential to realize micro-lasers with ultra-low optical losses. In this project, we aim to demonstrate electrically injected lasing in InP/InAsP multi-quantum well micro-ring cavities, grown using the selective area epitaxy technique.

Dr Wei Wen Wong, Dr Tuomas Haggren, Professor Hoe Tan, Professor Chennupati Jagadish

The effect of He irradiation on the microstructure and mechanical properties of W/ W alloys

Nuclear fusion is a promising technology for solving the world’s energy crisis while drastically reducing pollution and avoiding the creation of nuclear waste, a major issue for nuclear fission. However, there are many scientific and technical challenges to be overcome before this technology can be used for large-scale energy generation. One of the problems that need to be solved is the tolerance of the diverter walls to the high temperatures and He implantation – conditions that are prevalent inside the fusion reactors.

A/Prof Cormac Corr, Dr Matt Thompson

Solving the problem of how to measure a material harder than diamond

In experiments, measuring the hardness of a very hard material is fundamentally challenging. We aim to study the physical mechanics behind nanoindentation measurements to help better measure superhard materials.

Dr Xingshuo Huang, Prof Jodie Bradby

Ultrafast laser cleaning - The light touch

Laser Cleaning is a cutting-edge technique designed for removal of contamination layers from solid surfaces by irradiating the surface with a laser beam. It is a non-contact process, which does not require the use of chemicals or abrasives, eliminating problems of chemical toxicity, corrosive residues, and erasure of surface structure. 

Dr Ludovic Rapp

Characterisation of GeSn alloy film for making mid-infrared photodetector

This project investigates GeSn alloy thin films as a material for infrared photodetectors, focusing on the relationship between structural and electronic properties and their impact on device performance.

Dr Xingshuo Huang

X-ray scatter in 3D microscopes

X-ray scatter is most significant when imaging very dense/large samples: e.g. metal parts, large 3D printed components, or samples imaged on the CTLab's new "whole core" scanner. The student will develop methods to correct for its effects, both in-hardware (i.e. at the microscope) and in-software (i.e. image analysis).

Dr Andrew Kingston, Dr Glenn Myers, Prof Adrian Sheppard

Wearable III-V nanofilm photodetectors and sensors

Semiconductor nanofilms are just some tens of nanometres thick single-crystalline structures with lateral dimensions in cm-scale. The ultra-low thickness gives these films interesting properties differing from bulk materials, and enables interesting novel device concepts in photodetection and gas sensing.

Dr Tuomas Haggren, Professor Hoe Tan, Professor Chennupati Jagadish

Ultrashort laser processing for advanced applications

Laser processing is a cutting-edge technique designed for to clean, texture, enhance surfaces in a way not possible with any other method. It is a non-contact process, which does not require the use of chemicals or abrasives, thus eliminating problems of chemical toxicity and corrosive residues.

Dr Ludovic Rapp, Professor Andrei Rode

Deblur by defocus in a 3D X-ray microscope

This project will involve building a unified model of several theoretically-complex X-ray behaviours within the microscopes at the ANU CTLab, drawing from statistical and wave optics: spatial partial-coherence, refraction, and spectral interactions. The student will then apply this model to improve imaging capabilities at the ANU CTLab.

Dr Glenn Myers, Dr Andrew Kingston

Exciton polaritons in 2D atomically thin materials

This experimental project will focus on nvestigation of strong light-matter coupling and exciton polaritons in novel atomically thin materials.

Prof Elena Ostrovskaya, Professor Andrew Truscott

Employing machine learning-based methods in image processing for green iron ore

Dr Yulai Zhang, Dr Philipp Loesel, Dr Neelima Kandula, Dr Aleese Barron

Efficient optical interconnect for quantum computers

Superconducting and spin qubits are leading quantum computing technologies, but we currently have no way to connect them to optical quantum networks that will make up a future quantum internet. This project will develop an interconnect capable of efficiently converting microwave quantum information from these qubits to optical frequencies.

Dr Rose Ahlefeldt, Dr Lara Gillan

Nanofluidic diodes: from biosensors to water treatment

Controlling the flow of ions and molecules through nano-sized pores is fundamental in many biological processes and the basis for applications such as DNA detection, water desalination and drug delivery. The project aims to develop solid-state nanofluidic diodes and exploit their properties for applications in bio-sensors and ion-selective channels.

Prof Patrick Kluth

A gateway to new material states

This project explores how ultrafast, high-intensity lasers create exotic non-equilibrium material states by branching high-energy electrons and stabilising new crystalline or amorphous phases through ultrafast quenching. Students investigate fundamental mechanisms of relativistic laser–matter interactions, aiming to produce and analyse high-energy-density matter with unusual physical and chemical properties.

Dr Ludovic Rapp

Diagnosing plasma-surface interactions under fusion-relevant conditions

This project involves studying the complex plasma-surface interaction region of a fusion-relevant plasma environment through laser-based and spectroscopic techniques.

A/Prof Cormac Corr, Dr Matt Thompson

Nanoscience and Nanotechnology

III-V nanowire arrays for ultra-sensitive, selective, and flexible gas sensing applications

This project aims at design, fabrication, and characterisation of advanced III-V semiconductor nanowire gas sensors for environmental and healthcare monitoring.

Professor Lan Fu, Dr Zhe (Rex) Li

Positron Annihilation Spectroscopy

Understanding material defects at the atomic scale using anitmatter.

Dr Joshua Machacek, Professor Stephen Buckman

Directional metasurface lasers based on coupled nanowire pairs

We demonstrate directional emission from III-V nanowire lasers by engineering waveguide modes in optically coupled nanowire pairs. Arrays of such pairs enhance far-field directionality via non-local resonance, highlighting the potential of metasurface lasers as compact, coherent light sources for applications such as LiDAR and beam steering.

Dr Wei Wen Wong, Professor Hoe Tan, Professor Chennupati Jagadish

Controlling light with nanostructured surfaces

Metasurfaces are ultra-thin nanostructured materials that can shape and control light in extraordinary ways, but to be practical they must be tunable rather than fixed. This project develops liquid crystal–integrated metasurfaces to create reconfigurable flat optical devices for dynamic focusing, beam steering, and advanced sensing.

Professor Ilya Shadrivov, Dr Yana Izdebskaya, Dr Vladlen Shvedov

Optical metamaterials: fundamentals and applications

Experimental and theoretical work on the development of novel nanostructured materials with unusual optical properties. Special attention to our research is the development of tunable and functional nanostructured metamaterials that interact strongly with light. Such materials underpin novel optical technologies ranging from wearable sensors to night-vision devices.

Prof Dragomir Neshev

Nanowire lasers for applications in nanophotonics

This project aims to investigate the concepts and strategies required to produce electrically injected semiconductor nanowire lasers by understanding light interaction in nanowires, designing appropriate structures to inject current, engineer the optical profile and developing nano-fabrication technologies. Electrically operated nanowire lasers would enable practical applications in nanophotonics.

Professor Chennupati Jagadish, Professor Hoe Tan

High pressure creation of new forms of diamond

The hexagonal form of sp3 bonded carbon is predicted to be harder than 'normal' cubic diamond. We can make tiny amounts of this new form of diamond and want to know if it really is harder than diamond.

Prof Jodie Bradby, Dr Xingshuo Huang

Nanowire photonic crystal surface-emitting lasers

In this project, we aim to demonstrate photonic crystal surface-emitting lasers (PCSELs) constructed from vertically-standing III-V semiconductor nanowires as the fundamental building blocks. We will also explore more advanced nanowire-based PCSEL designs, including hetero-lattice PCSELs with enhanced in-plane optical feedback and topological PCSELs.

Dr Wei Wen Wong, Professor Hoe Tan, Professor Chennupati Jagadish

Solid-state nanopore sensors: Unveiling new frontiers in biomolecule detection

Investigate novel nanopore bio-sensors using nanofabrication, bio-chemsity and machine learning.

Prof Patrick Kluth

Nanowire infrared avalanche photodetectors towards single photon detection

This project aims to demonstrate semiconductor nanowire based infrared avalanche photodetectors (APDs) with ultra-high sensitivity towards single photon detection. By employing the advantages of their unique one-dimensional nanoscale geometry, the nanowire APDs can be engineered to different device architectures to achieve performance superior to their conventional counterparts. This will contribute to the development of next generation infrared photodetector technology enabling numerous emerging fields in modern transportation, communication, quantum computation and information processing.

Professor Lan Fu, Dr Zhe (Rex) Li, Professor Chennupati Jagadish

Positron interactions with structured surfaces

We are investigating novel effects and applications using positrons and structured surfaces.

Dr Joshua Machacek, Dr Sergey Kruk

Shape engineering of semiconductor nanostructures for novel device applications

This project aims to investigate the growth of III-V semiconductors on pre-patterned nanotemplates. By using different shapes and geometries, it is envisaged that these nanostructures will provide novel architectures for advanced, next generation optoelectronic devices.

Professor Hoe Tan, Professor Chennupati Jagadish

Resonant metasurfaces for enhanced frequency conversion

This project explores the design and development of nonlinear metasurfaces, ultrathin layered nanostructures capable of enhancing frequency conversion. Using novel design methods, the student will contribute to fabricate and experimentally test free-form metasurfaces with optimised efficiency, directionality, and polarisation, ultimately demonstrating metasurfaces that can surpass the performance of conventional designs.

Dr Maria del Rocio Camacho-Morales, Prof Dragomir Neshev

Functional nanopore membranes

Nano-pore membranes have important applications in chemical- and bio-sensing, water filtration and protein separation. This project will investigate our innovative technology to fabricate nanopore membranes in silicon dioxide and silicon nitride and exploit their use for advanced applications.

Prof Patrick Kluth

Electrically injected metasurface lasers

Metasurfaces have emerged as a cornerstone for next-generation optics and optoelectronics. This project aims to create metasurface lasers from III-V semiconductor thin-films, that are additionally pumped electrically.  

Dr Tuomas Haggren, Professor Hoe Tan, Professor Chennupati Jagadish

Laser-written nanostructures for future photonics

Use lasers to sculpt matter at the nanoscale! In this project you’ll create shimmering holographic patterns and functional nanostructures on metals and glasses, exploring their applications in photonics, anti-counterfeiting, and smart coatings—all while uncovering the physics of light–matter interaction.

Professor Ilya Shadrivov, Dr Vladlen Shvedov, Dr Yana Izdebskaya

Wearable III-V nanofilm photodetectors and sensors

Semiconductor nanofilms are just some tens of nanometres thick single-crystalline structures with lateral dimensions in cm-scale. The ultra-low thickness gives these films interesting properties differing from bulk materials, and enables interesting novel device concepts in photodetection and gas sensing.

Dr Tuomas Haggren, Professor Hoe Tan, Professor Chennupati Jagadish

Terahertz polarisation optics

This project will pioneer compact, low-loss terahertz polarisation optics—polarisers, waveplates, and circular polarisers—by harnessing artificial birefringence in metamaterials to overcome the limitations of natural crystals.

Professor Ilya Shadrivov, Mr Oleg Kameshkov, Dr Vladlen Shvedov

Quantum-well nanowire light emitting devices

In this project we aim to design and demonstrate  III-V compound semiconductor based quantum well nanowire light emitting devices with wavelength ranging from 1.3 to 1.6 μm for optical communication applications.

Professor Lan Fu, Dr Zhe (Rex) Li, Professor Hoe Tan, Professor Chennupati Jagadish

Nanofluidic diodes: from biosensors to water treatment

Controlling the flow of ions and molecules through nano-sized pores is fundamental in many biological processes and the basis for applications such as DNA detection, water desalination and drug delivery. The project aims to develop solid-state nanofluidic diodes and exploit their properties for applications in bio-sensors and ion-selective channels.

Prof Patrick Kluth

Photonics, Lasers and Nonlinear Optics

Non-equilibrium quantum condensation of microcavity exciton polaritons

This project combines theoretical and experimental research on exciton polaritons in semiconductor microcavities. We investigate emergent quantum phenomena far from equilibrium and their applications for next-generation optoelectronics devices.

Prof Elena Ostrovskaya, Professor Andrew Truscott

Quantum squeezed states for interferometric gravitational-wave detectors

Using non-classical light states on laser interferometric gravitational-wave detectors, to further enhance the best length measurement devices in the world.

Professor Robert Ward, A/Prof Bram Slagmolen, Distinguished Prof David McClelland

Developing ultra-high resolution optical meta-surface sensors

The project aims to develop methods to improve the sensitivity of optical metasurfaces for the detection of chemical and biological markers. By tailoring a high-precision optical interferometric sensing solution to the optical properties of a metasurface under-test, the project will improve the sensitivity of these devices, developing a new range of targeted ultra-precise metasurface sensors.

Dr Chathura Bandutunga , Prof Dragomir Neshev

Machine learning for optics and controls

Optical cavities are widely used in physics and precision measurement.  This project will explore the use of modern machine learning methods for the control of suspended optical cavities.

A/Prof Bram Slagmolen, Dr Jiayi Qin, Professor Robert Ward

Mid-infrared single-mode waveguides for the LIFE space mission

The Large Interferometer for Exoplanets (LIFE) aims to detect biosignatures on Earth-like planets by collecting mid-infrared spectra. A major challenge is creating low-loss waveguides for spatial filtering. This project explores photonic crystal waveguides, using femtosecond lasers and Bessel beams to fabricate microstructures in transparent crystals for efficient light guidance.

Dr Ludovic Rapp, Dr Shan Liu

Harnessing non-classical correlations of exciton-polariton condensates

This project aims to experimentally probe and manipulate the non-classical properties of exciton polariton condensates, which will pave the way for tunable generation of quantum light on a semiconductor chip.

Dr Eliezer Estrecho, Prof Elena Ostrovskaya, Professor Andrew Truscott

Directional metasurface lasers based on coupled nanowire pairs

We demonstrate directional emission from III-V nanowire lasers by engineering waveguide modes in optically coupled nanowire pairs. Arrays of such pairs enhance far-field directionality via non-local resonance, highlighting the potential of metasurface lasers as compact, coherent light sources for applications such as LiDAR and beam steering.

Dr Wei Wen Wong, Professor Hoe Tan, Professor Chennupati Jagadish

Synthesising non-Hermitian gauge fields for microcavity exciton polaritons

This project aims to realise various useful artificial gauge fields for cavity photons and exciton polaritons. These fields are expected to be non-Hermitian and can be used to combine effects of non-Hermiticity and topology, e.g. topological edge states and non-Hermitian skin effect. Realising these non-Hermitian fields is an important step towards practical applications of exciton-polariton condensates and superfluids.

Dr Eliezer Estrecho, Prof Elena Ostrovskaya

Nano-scale III-V light emitters on Si

Although planar growth of III-V materials on Si has been widely demonstrated, direct growth of III-V nanostructures on Si remains challenging. This project aims to realize InP/InAsP light-emitting nanostructures on Si substrates by engineering the III-V/Si interfacial energy, enabling monolithic integration of active photonic components on silicon.

Dr Wei Wen Wong, Professor Hoe Tan, Professor Chennupati Jagadish

Controlling light with nanostructured surfaces

Metasurfaces are ultra-thin nanostructured materials that can shape and control light in extraordinary ways, but to be practical they must be tunable rather than fixed. This project develops liquid crystal–integrated metasurfaces to create reconfigurable flat optical devices for dynamic focusing, beam steering, and advanced sensing.

Professor Ilya Shadrivov, Dr Yana Izdebskaya, Dr Vladlen Shvedov

Optical metamaterials: fundamentals and applications

Experimental and theoretical work on the development of novel nanostructured materials with unusual optical properties. Special attention to our research is the development of tunable and functional nanostructured metamaterials that interact strongly with light. Such materials underpin novel optical technologies ranging from wearable sensors to night-vision devices.

Prof Dragomir Neshev

Nanowire lasers for applications in nanophotonics

This project aims to investigate the concepts and strategies required to produce electrically injected semiconductor nanowire lasers by understanding light interaction in nanowires, designing appropriate structures to inject current, engineer the optical profile and developing nano-fabrication technologies. Electrically operated nanowire lasers would enable practical applications in nanophotonics.

Professor Chennupati Jagadish, Professor Hoe Tan

Optical nanoantennas

Antennas are at the heart of modern radio and microwave frequency communications technologies. They are the front-ends in satellites, cell-phones, laptops and other devices that make communication by sending and receiving radio waves. This project aims to design analog of optical nanoantennas for visible light for advanced optical communiction. 

Prof Dragomir Neshev

Bottom-up, parity-time (PT) symmetric micro-cavity lasers

In this project, we aim to explore PT-symmetric lasing in III-V semiconductor micro-cavity lasers that are epitaxially grown on their substrates, free from any etching-induced damage. In particular, we aim to demonstrate performance improvements by exploiting some of the unique features of bottom-up grown laser cavities.

Dr Wei Wen Wong, Professor Hoe Tan, Professor Chennupati Jagadish

Nanowire photodetectors for photonic and quantum systems

Semiconductor nanowires are emerging nano-materials with substantial opportunities for novel photonic and quantum device applications. This project aims at developing a new generation of high performance NW based photodetectors for a wide range of applications.

Professor Lan Fu, Dr Zhe (Rex) Li, Professor Chennupati Jagadish

Nanowire photonic crystal surface-emitting lasers

In this project, we aim to demonstrate photonic crystal surface-emitting lasers (PCSELs) constructed from vertically-standing III-V semiconductor nanowires as the fundamental building blocks. We will also explore more advanced nanowire-based PCSEL designs, including hetero-lattice PCSELs with enhanced in-plane optical feedback and topological PCSELs.

Dr Wei Wen Wong, Professor Hoe Tan, Professor Chennupati Jagadish

Engineering Inter-spacecraft laser links

Inter-satellite laser links are an emerging technology with applications in Earth Observation, telecommunications, security, and, the focus of the CGA space technology group.

Professor Kirk McKenzie, Dr Andrew Wade, Dr Ya Zhang, Ms Emily Rose Rees

Nanowire infrared avalanche photodetectors towards single photon detection

This project aims to demonstrate semiconductor nanowire based infrared avalanche photodetectors (APDs) with ultra-high sensitivity towards single photon detection. By employing the advantages of their unique one-dimensional nanoscale geometry, the nanowire APDs can be engineered to different device architectures to achieve performance superior to their conventional counterparts. This will contribute to the development of next generation infrared photodetector technology enabling numerous emerging fields in modern transportation, communication, quantum computation and information processing.

Professor Lan Fu, Dr Zhe (Rex) Li, Professor Chennupati Jagadish

Positron interactions with structured surfaces

We are investigating novel effects and applications using positrons and structured surfaces.

Dr Joshua Machacek, Dr Sergey Kruk

Bottom-up, quasi-bound states in the continuum (quasi-BIC) metasurface lasers

This project aims to demonstrate lasing in a bottom-up metasurface supporting a perturbed symmetry-protected quasi-BIC mode, while exploring its unique optical properties. We will also develop fabrication processes to achieve electrically injected lasing, highlighting the advantages of bottom-up metasurface design over conventional top-down laser fabrication approaches.

Dr Wei Wen Wong, Professor Hoe Tan, Professor Chennupati Jagadish

Resonant metasurfaces for enhanced frequency conversion

This project explores the design and development of nonlinear metasurfaces, ultrathin layered nanostructures capable of enhancing frequency conversion. Using novel design methods, the student will contribute to fabricate and experimentally test free-form metasurfaces with optimised efficiency, directionality, and polarisation, ultimately demonstrating metasurfaces that can surpass the performance of conventional designs.

Dr Maria del Rocio Camacho-Morales, Prof Dragomir Neshev

Electrically injected metasurface lasers

Metasurfaces have emerged as a cornerstone for next-generation optics and optoelectronics. This project aims to create metasurface lasers from III-V semiconductor thin-films, that are additionally pumped electrically.  

Dr Tuomas Haggren, Professor Hoe Tan, Professor Chennupati Jagadish

Femtosecond laser cleaning of Aboriginal rock art

This project develops safe, damage-free laser cleaning for Australian Indigenous rock art and historic stone monuments, removing contaminants without altering surfaces. Using ultrashort pulse lasers at multiple wavelengths, it combines laboratory optimization and field-applicable procedures, in collaboration with heritage partners and Indigenous custodians, to restore and preserve culturally and visually significant sites.

Dr Ludovic Rapp, Dr Ksenia Maximova

Metasurface polarization optics and quantum photonics

This project aims for developing polarization optical devices based on all-dielectric metasurfaces. As no bulky optical elements and moving parts are required, these devices are compact, stable, and can operate in a single-shot mode with high time resolution. Potential applications include sensitive biological imaging and quantum state manipulation and tomography. 

Prof Andrey Sukhorukov

Electrically-injected bottom-up III-V micro-cavity lasers

Bottom-up fabrication of lasers via epitaxial growth is emerging as a promising alternative to conventional top-down methods, offering potential to realize micro-lasers with ultra-low optical losses. In this project, we aim to demonstrate electrically injected lasing in InP/InAsP multi-quantum well micro-ring cavities, grown using the selective area epitaxy technique.

Dr Wei Wen Wong, Dr Tuomas Haggren, Professor Hoe Tan, Professor Chennupati Jagadish

Machining learning for coupled interferometer alignment and control

This project aims to develop a three-mirror coupled optical cavity system with automated alignment and control. Machine learning will be used to identify optical modes and optimize cavity operation, enabling advanced studies in precision optical control and interferometry.

Dr Jiayi Qin, A/Prof Bram Slagmolen, Professor Robert Ward

Nonlinear topological photonics

The project bridges the fundamental physics of topological phases with nonlinear optics. This promising synergy is expected to unlock advanced functionalities for applications in optical sources, frequency combs, isolators and multiplexers, switches and modulators, both for classical and quantum light. 

Dr Daria Smirnova

Ultrafast laser cleaning - The light touch

Laser Cleaning is a cutting-edge technique designed for removal of contamination layers from solid surfaces by irradiating the surface with a laser beam. It is a non-contact process, which does not require the use of chemicals or abrasives, eliminating problems of chemical toxicity, corrosive residues, and erasure of surface structure. 

Dr Ludovic Rapp

Laser-written nanostructures for future photonics

Use lasers to sculpt matter at the nanoscale! In this project you’ll create shimmering holographic patterns and functional nanostructures on metals and glasses, exploring their applications in photonics, anti-counterfeiting, and smart coatings—all while uncovering the physics of light–matter interaction.

Professor Ilya Shadrivov, Dr Vladlen Shvedov, Dr Yana Izdebskaya

Quantum photonics with nanostructured metasurfaces

Metasurface can the generation and manipulation of polarization-entangled photon pairs at the nanoscale.

Prof Andrey Sukhorukov

Ultrashort laser processing for advanced applications

Laser processing is a cutting-edge technique designed for to clean, texture, enhance surfaces in a way not possible with any other method. It is a non-contact process, which does not require the use of chemicals or abrasives, thus eliminating problems of chemical toxicity and corrosive residues.

Dr Ludovic Rapp, Professor Andrei Rode

Exciton polaritons in 2D atomically thin materials

This experimental project will focus on nvestigation of strong light-matter coupling and exciton polaritons in novel atomically thin materials.

Prof Elena Ostrovskaya, Professor Andrew Truscott

Fibre optic sensor arrays for vibrometry and acoustic sensing

By leveraging hybrid digital-optical methods, we develop new distributed and quasi-distributed fibre-optic acoustic sensors. These acoustic sensors aim to measure vibration, strain and displacement all while localising the signal source along an optical fibre.

Dr Chathura Bandutunga , A/Prof Bram Slagmolen

Higher-order mode displacement sensors

A project to advance a prototype displacement sensor to test-type phase, via improved compact mechanical design,  vacuum compatibility, and improved sensor testing.

Dr Sheon Chua, A/Prof Bram Slagmolen

Quantum-well nanowire light emitting devices

In this project we aim to design and demonstrate  III-V compound semiconductor based quantum well nanowire light emitting devices with wavelength ranging from 1.3 to 1.6 μm for optical communication applications.

Professor Lan Fu, Dr Zhe (Rex) Li, Professor Hoe Tan, Professor Chennupati Jagadish

A gateway to new material states

This project explores how ultrafast, high-intensity lasers create exotic non-equilibrium material states by branching high-energy electrons and stabilising new crystalline or amorphous phases through ultrafast quenching. Students investigate fundamental mechanisms of relativistic laser–matter interactions, aiming to produce and analyse high-energy-density matter with unusual physical and chemical properties.

Dr Ludovic Rapp

Femtosecond laser for ultra-precise cavity drilling in modern dentistry

Development of efficient, versatile and fast laser femtosecond processes for advanced applications in modern dentistry promising a precise pain-free dental treatment for all patients.

Dr Ludovic Rapp

Physics of Fluids

Understanding drought-resistance in Australian plants with 3D X-ray microscopy

This project will use unique, ANU-designed 3D X-ray microscopes and state-of-the art image analysis to track physiological responses of drought-tolerant Australian plants when subjected to water stress. The results will help us understand the mechanisms that underpin drought-tolerance, helping resolve ongoing debates and helping understand which forest eco-systems that are most vulnerable to climate change, and why.

Prof Adrian Sheppard, Dr Levi Beeching, Dr Andrew Kingston

Controlling quantum turbulence in atomic superfluids

Turbulence is one of the most important unsolved problems in modern physics, underpinning universal phenomena from galactic formation to heat and pollutant transport in our atmosphere and oceans. This project seeks to theoretically investigate turbulence in superfluids, and introduce methods of controlling the system dynamics using quantum feedback control.

Dr Zain Mehdi, Dr Simon Haine, Professor Joseph Hope

Imaging CO2 storage in coal with X-ray microCT

This project will use X-ray microCT imaging and advanced image analysis methods to investigate CO2 injection in coal, providing new insights into the potential of coal seams for CO2 storage.

Dr Yulai Zhang

Physics of the Nucleus

Neutron stars: understanding physics at the extreme

Neutron stars are a unique laboratory for probing physics under the greatest extremes of density and gravity, far beyond what is capable in terrestrial laboratories.  This project aims to use gravitational wave discoveries and electromagnetic observations of neutron stars to examine fundamental physics.

Dr Karl Wette, Distinguished Prof Susan Scott

The intersection of nuclear structure and nuclear scattering

This project explores nuclear scattering using shell-model-derived potentials to better understand complex nuclear interactions. Students will enhance coding skills, deepen quantum mechanics knowledge, and apply high-performance computing to study processes relevant to nuclear astrophysics and nucleosynthesis, shedding light on the origins of the chemical elements. 

Professor Cedric Simenel

Exotic nuclear structure towards the neutron dripline

Investigate the structure and radioactive-decay properties of exotic nuclei, and the roles they play in advancing modern nuclear theory, stella nucleosynthesis and applications of nuclear technology in society. 

Dr AJ Mitchell, Professor Gregory Lane

Radon control in directional dark matter detectors

Directional dark matter searches provide a way to probe beyond the irreducible ‘neutrino fog’ that limits traditional dark matter experiments. CYGNUS-OZ is part of the global directional dark matter effort, and this project focuses on the critical challenge of radon control in these detectors.

Dr Robert Renz Marcelo Gregorio, Dr Lindsey Bignell, Professor Gregory Lane

Nuclear structure studies with particle transfer reactions

This project will use nuclear reactions to study the basic make-up of atomic nuclei at the quantum level, and investigate the impact of nuclear structure on sub-atomic forces and fundamental physics. 

Dr AJ Mitchell, Professor Gregory Lane, Emeritus Professor Andrew Stuchbery

Nuclear batteries: Energy-storage applications of nuclear isomers

Nuclear metastable states, known colloquially as isomers, have energy densities millions of times greater than chemical batteries. This project investigates nuclear pathways for reliably extracting this energy from candidate isotopes on demand. 

Dr AJ Mitchell, Professor Gregory Lane

How do we make the next superheavy nucleus?

This project aims to make measurements that help inform us on how new superheavy elements can be made in the lab. 

Dr Kaitlin Cook, Dr Jacob Buete, Professor Mahananda Dasgupta, Emeritus Professor David Hinde

Radioimpurities in particle detectors for dark matter studies

This experiment will characterise dark matter detector material. Lowest levels of natural radioactivity in high purity samples will be analysed via ultra-senstive single atom counting using acclerator mass spectrometry.

Dr Michaela Froehlich , Dr Yiyi Zhong, Dr Zuzana Slavkovska, A/Prof Stephen Tims

Impact of nuclear structure on dark matter direct detection

Quantum many-body modelling of the atomic nucleus will help us understand how dark matter particles interact with atomic nuclei, as well as how many scattering events we can expect in underground laboratory search for dark matter. 

Ms Raghda Abdel Khaleq, Mr Navneet Krishnan, Professor Cedric Simenel

Nuclear vibrations in near-spherical and deformed nuclei

This project aims to discover if the long-held concept of low-energy nuclear vibrations holds true under scrutiny from Coulomb excitation and nucleon-transfer reactions. 

Emeritus Professor Andrew Stuchbery, Professor Gregory Lane, Dr AJ Mitchell

Towards a global understanding of nuclear fission

Improved understandings of nuclear fission is key for many areas of science, including heavy element formation in supernova and neutron-star mergers, making safer nuclear reactors, and the formation and properties of long-lived superheavy isotopes. Students involved in this project will further our understanding of fission across the chart of nuclides.

Dr Kaitlin Cook, Emeritus Professor David Hinde, Professor Mahananda Dasgupta, Dr Jacob Buete

Advanced detector development for rare event particle physics

Experimental, simulation, and data analysis projects are available to help develop advanced detection technology which will form the basis of a future large particle physics experiment in Australia

Dr Lindsey Bignell, Dr Robert Renz Marcelo Gregorio, Miss Victoria Bashu, Professor Gregory Lane

Time dependence of nuclear fusion

This project will allow us to understand the time-dependence of quantum tunnelling and nuclear fusion.

Dr Edward Simpson

Understanding energy dissipation in colliding quantum many-body systems

This project aims to gain fundamental insights into the mechanisms of energy dissipation in nuclear collisions by making new measurements that will aid in the development of new models of nuclear fusion.

Dr Kaitlin Cook, Professor Mahananda Dasgupta, Emeritus Professor David Hinde, Dr Jacob Buete

Ultra-fast lifetime measurements of nuclear excited states

Use ultra-fast gamma-ray detectors to perform excited-state lifetime measurements and investigate single-particle and collective features of atomic nuclei. 

Professor Gregory Lane, Dr AJ Mitchell, Emeritus Professor Andrew Stuchbery, Emeritus Professor Tibor Kibedi

Simulating cosmic-ray interactions with materials for dark matter searching and commercial applications

This project uses Geant4 simulations to investigate how naturally occurring cosmic rays interact with materials relevant to physics and environmental research, including NaI(Tl) crystals, gaseous detectors, and soil.

Dr Yiyi Zhong, Dr Lindsey Bignell

Plasma Applications and Technology

High pressure non-equilibrium plasma discharges in chemically reactive systems

The goal of this research is to study high pressure non-equilibrium plasma discharges in chemically reactive systems with applications to space, waste treatment and material science.

A/Prof Cormac Corr

Quantum Science and Technology

Non-equilibrium quantum condensation of microcavity exciton polaritons

This project combines theoretical and experimental research on exciton polaritons in semiconductor microcavities. We investigate emergent quantum phenomena far from equilibrium and their applications for next-generation optoelectronics devices.

Prof Elena Ostrovskaya, Professor Andrew Truscott

Quantum squeezed states for interferometric gravitational-wave detectors

Using non-classical light states on laser interferometric gravitational-wave detectors, to further enhance the best length measurement devices in the world.

Professor Robert Ward, A/Prof Bram Slagmolen, Distinguished Prof David McClelland

Beam matching using machine learning

This project aims to use a machine learning algorithm to perform beam alignment in an optics experiment. It would involve mode-matching two optical beams using motorised mirror mounts. Additional degrees of freedom like lens positions and beam polarisation can be added later.

Dr Aaron Tranter

Harnessing non-classical correlations of exciton-polariton condensates

This project aims to experimentally probe and manipulate the non-classical properties of exciton polariton condensates, which will pave the way for tunable generation of quantum light on a semiconductor chip.

Dr Eliezer Estrecho, Prof Elena Ostrovskaya, Professor Andrew Truscott

Exploring physics with neural networks

Machine learning based on deep neural networks is a powerful method for improving the performance of experiments.  It may also be useful for finding new physics.

Dr Aaron Tranter, Professor Ben Buchler, Professor Ping Koy Lam

Mass-entangled ultracold helium atoms

This experimental project aims to create entangled states of ultracold helium atoms where the entanglement is between atoms of different mass. By manipulating the entangled pairs using laser induced Bragg transitions and measuring the resulting correlations, we will study how gravity affects mass-entangled particles.

Dr Sean Hodgman, Professor Andrew Truscott

Synthesising non-Hermitian gauge fields for microcavity exciton polaritons

This project aims to realise various useful artificial gauge fields for cavity photons and exciton polaritons. These fields are expected to be non-Hermitian and can be used to combine effects of non-Hermiticity and topology, e.g. topological edge states and non-Hermitian skin effect. Realising these non-Hermitian fields is an important step towards practical applications of exciton-polariton condensates and superfluids.

Dr Eliezer Estrecho, Prof Elena Ostrovskaya

Quantum chemistry modelling of rare earth crystals for quantum technologies

Quantum technology applications of rare earth crystals would benefit from accurate ab-initio models of how quantum properties arise from fundamental atom-atom interactions in crystals. In this project, we will adapt recent advances in molecular quantum chemistry models to rare earth crystals and apply them to quantum technology problems.

Dr Rose Ahlefeldt

Shining new light on the ‘proton radius puzzle’ using ultracold helium

This experimental project, involves building an ultra-stable frequency laser which will be used to probe electronic transitions in ultracold - 3He and 4He.  These measurements will then be used to determine the differential isotopic nuclear charge radius of helium to a world leading absolute accuracy.

Professor Andrew Truscott, Dr Sean Hodgman

Atomic magnetometer for exploring physics beyond the standard model and gyroscopy

Atomic sensors are exquisitely sensitive. We aim to model and build a new generation of atomic sensors to measure magnetic fields, rotation and dark matter. 

Professor Ben Buchler

Dual torsion pendulum for quantum noise limited sensing

Construct a small dual tosion pendulum which have their centre of mass co-incide and their rotational axis colinear. Inital diagnostics will be done using shadow sensors.

A/Prof Bram Slagmolen, Dr Sheon Chua, Professor Robert Ward

Miniature absolute gravimeter

Absolute gravimeters tie their measurement of gravity to the definition of the second 
by interrogating the position of a falling test mass using a laser interferometer. Our vision is to develop and prototype a miniaturised absolute gravimeter by 
leveraging modern vacuum, laser, and micro-electromechanical systems.

Dr Samuel Legge, Professor John Close

Vibration control for optical interferometry

Develop an active vibraiton isolation platform to provide a quiet, small displacement environment for high precision inteferometry.

A/Prof Bram Slagmolen, Dr Sheon Chua, Professor Robert Ward

Femtosecond laser cleaning of Aboriginal rock art

This project develops safe, damage-free laser cleaning for Australian Indigenous rock art and historic stone monuments, removing contaminants without altering surfaces. Using ultrashort pulse lasers at multiple wavelengths, it combines laboratory optimization and field-applicable procedures, in collaboration with heritage partners and Indigenous custodians, to restore and preserve culturally and visually significant sites.

Dr Ludovic Rapp, Dr Ksenia Maximova

Metasurface polarization optics and quantum photonics

This project aims for developing polarization optical devices based on all-dielectric metasurfaces. As no bulky optical elements and moving parts are required, these devices are compact, stable, and can operate in a single-shot mode with high time resolution. Potential applications include sensitive biological imaging and quantum state manipulation and tomography. 

Prof Andrey Sukhorukov

Prospects of future ground-based gravitational-wave detector network

In this project, we study the gravitational-wave astronomy and astrophysics science cases and observational prospects with future ground-based gravitational-wave observatories.

Dr Lilli (Ling) Sun, A/Prof Bram Slagmolen, Distinguished Prof David McClelland

Atom-light interactions in quantum memories

Quantum memories store light in atomic ensembles for applications in quantum computing and networking. This project explores how atoms and light interact in prototype quantum memories that use rare earth atoms in crystals for storage, aiming to improve memory efficiency,  storage capacity, and performance in real-world devices.

Dr Rose Ahlefeldt, Dr James Stuart

Experimental quantum simulation with ultracold metastable Helium atoms in an optical lattice

This project will construct a 3D optical lattice apparatus for ultracold metastable Helium atoms, which will form an experimental quantum-simulator to investigate quantum many-body physics. A range of experiments will be performed such as studying higher order quantum correlations across the superfluid to Mott insulator phase transition.

Dr Sean Hodgman, Professor Andrew Truscott

Quantum photonics with nanostructured metasurfaces

Metasurface can the generation and manipulation of polarization-entangled photon pairs at the nanoscale.

Prof Andrey Sukhorukov

Interactions between antimatter and ultracold atoms

Antiparticles and antimatter have progressed from theory and science fiction to become an important and exciting area of pure and applied science. This fundamental atomic physics project will investigate how antimatter and matter interact by experimentally studying the interaction of positrons (the electron anti-particle) with trapped ultracold rubidium atoms.

Dr Sean Hodgman, Professor Stephen Buckman, Dr Joshua Machacek

Controlling quantum turbulence in atomic superfluids

Turbulence is one of the most important unsolved problems in modern physics, underpinning universal phenomena from galactic formation to heat and pollutant transport in our atmosphere and oceans. This project seeks to theoretically investigate turbulence in superfluids, and introduce methods of controlling the system dynamics using quantum feedback control.

Dr Zain Mehdi, Dr Simon Haine, Professor Joseph Hope

Efficient optical interconnect for quantum computers

Superconducting and spin qubits are leading quantum computing technologies, but we currently have no way to connect them to optical quantum networks that will make up a future quantum internet. This project will develop an interconnect capable of efficiently converting microwave quantum information from these qubits to optical frequencies.

Dr Rose Ahlefeldt, Dr Lara Gillan

Exploring the many body physics in an atomic matterwave system with PT symmetry

Investigating the possible enhancement of sensitivity in atomic sensors with PT symmetry and the underlying many body evolution.

Dr Jessica Eastman, Dr Simon Haine

Theoretical Physics

Introduction to quantum integrable systems

The aim of this project is to introduce quantum integrable systems which play a very important role in modern theoretical physics. Such systems provide one of very few ways to analyze nonlinear effects in continuous and discrete quantum systems.

A/Prof Vladimir Mangazeev

Stochastic dynamics of interacting systems and integrability

There are many interesting physical statistical systems which never reach thermal equilibrium. Examples include surface growth, diffusion processes or traffic flow. In the absence of general theory of such systems a study of particular models plays a very important role. Integrable systems provide examples of such systems where one can analyze time dynamics using analytic methods.

A/Prof Vladimir Mangazeev

A computational method to detect and quantify symmetry

Apply methods from topological data analysis to derive a new approach to quantifying the geometric symmetries of three-dimensional shapes. 

Dr Vanessa Robins

Optical nanoantennas

Antennas are at the heart of modern radio and microwave frequency communications technologies. They are the front-ends in satellites, cell-phones, laptops and other devices that make communication by sending and receiving radio waves. This project aims to design analog of optical nanoantennas for visible light for advanced optical communiction. 

Prof Dragomir Neshev

Impact of nuclear structure on dark matter direct detection

Quantum many-body modelling of the atomic nucleus will help us understand how dark matter particles interact with atomic nuclei, as well as how many scattering events we can expect in underground laboratory search for dark matter. 

Ms Raghda Abdel Khaleq, Mr Navneet Krishnan, Professor Cedric Simenel

Continuous gravitational waves: new methods for new discoveries

The next big discovery in gravitational wave astronomy may be a first detection of continuous gravitational waves from rapidly-spinning neutron stars. This projects aims to develop the data analysis methods needed for such a discovery.

Dr Karl Wette, Distinguished Prof Susan Scott

Motions of crystalline bar-joint frameworks

Periodic frameworks, viewed as simple mechanisms, can be rigid or display a variety of exotic deformation properties such as surface modes or expansive auxetic motion. This project will conduct a systematic search for frameworks with these properties. 

Dr Vanessa Robins

Time dependence of nuclear fusion

This project will allow us to understand the time-dependence of quantum tunnelling and nuclear fusion.

Dr Edward Simpson

Topological data analysis

A range of projects are available applying and developing the tools of topological data analysis. Data include 2D and 3D digital images, structural motifs in molecular-dynamics simulations, porous materials and more. 

Dr Vanessa Robins

How does a black hole ring?

We study the numerical waveforms for the gravitational waves emitted during the black hole ringdown stage, implement tools and data analysis frameworks, and analyze the latest gravitational-wave data to estimate black hole properties and test the general theory of relativity.

Dr Lilli (Ling) Sun, Distinguished Prof Susan Scott

When two neutron stars collide, what is left behind?

In 2017, the first discovery of gravitational waves from two colliding neutron stars heralded a new age of multi-messenger astronomy. But what was left over after the collision? This project aims to find out.

Dr Karl Wette, Distinguished Prof Susan Scott

Foundations of quantum tunnelling

The project is to improve our understanding and description of quantum tunnelling of interacting particles using tools from quantum field theory, quantum many-body systems, and quantum information. 

Professor Cedric Simenel

Topological and Structural Science

A computational method to detect and quantify symmetry

Apply methods from topological data analysis to derive a new approach to quantifying the geometric symmetries of three-dimensional shapes. 

Dr Vanessa Robins

Motions of crystalline bar-joint frameworks

Periodic frameworks, viewed as simple mechanisms, can be rigid or display a variety of exotic deformation properties such as surface modes or expansive auxetic motion. This project will conduct a systematic search for frameworks with these properties. 

Dr Vanessa Robins

Nonlinear topological photonics

The project bridges the fundamental physics of topological phases with nonlinear optics. This promising synergy is expected to unlock advanced functionalities for applications in optical sources, frequency combs, isolators and multiplexers, switches and modulators, both for classical and quantum light. 

Dr Daria Smirnova

Topological data analysis

A range of projects are available applying and developing the tools of topological data analysis. Data include 2D and 3D digital images, structural motifs in molecular-dynamics simulations, porous materials and more. 

Dr Vanessa Robins

Wood-based mechanical metamaterials

The field of mechanical metamaterials is a fast-developing research domain, here the project aims at studying and developping wood-based and wood-inspired metamaterials.

Associate Professor Nicolas Francois, Dr Mohammad Saadatfar, Professor Mark Knackstedt

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