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

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

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

Materials Science and Engineering

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

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 Ziyuan Li, Professor Hoe Tan

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

Nano-scale III-V light emitters on Si

While there have been numerous demonstrations of planar growth of III-V materials on Si substrates, growing III-V nanostructures directly on Si is not a trivial task. In this project, we aim to demonstrate the direct growth of InP/InAsP light-emitting nanostructures on Si substrates by engineering the III-V/Si interfacial energy. 

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

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

Bottom-up fabrication of lasers via epitaxial growth has been emerging as a promising alternative to the conventional top-down fabrication methods. In this project, we aim to demonstrate electrically-injected lasing in InP/InAsP multi-quantum well micro-ring cavities that are grown by the selective area epitaxy technique.

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

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

In this project, we aim to demonstrate lasing in a bottom-up metasurface device supporting a perturbed symmetry-protected, quasi-BIC mode. The unit cell of the metasurface consists of a pair of InP nanosheet structures that are grown with the selective area epitaxy technique. 

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

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

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

Nanoscience and Nanotechnology

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

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 Ziyuan Li, Professor Hoe Tan, Professor Chennupati Jagadish

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

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

Optical metamaterials: from science fiction to transformative optical technologies

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, Dr Andrei Komar, Dr Mohsen Rahmani

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

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

Photonics, Lasers and Nonlinear Optics

Integrated quantum photonics

The goal of the project is to understand new physical phenomena arising from quantum and nonlinear optical integration. In the future this research may open doors to new types of computers and simulators with information capacity exceeding the number of elementary particles in the entire universe.

Prof Andrey Sukhorukov, Dr Jinyong Ma, Dr Jihua Zhang, Prof Dragomir Neshev

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 Ziyuan Li, 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 Ziyuan Li, Professor Hoe Tan

Synthetic multi-dimensional photonics

This project goal is to investigate, theoretically and experimentally, photonic systems with synthetic dimensionality exceeding the three spatial dimensions, and reveal new opportunities for applications in optical signal switching and sensing in classical and quantum photonics.

Prof Andrey Sukhorukov, Dr Jihua Zhang

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

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

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

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

Optical metamaterials: from science fiction to transformative optical technologies

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, Dr Andrei Komar, Dr Mohsen Rahmani

Quantum photonics with nanostructured metasurfaces

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

Dr Jinyong Ma, Prof Andrey Sukhorukov, Dr Jihua Zhang

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

Nano-scale III-V light emitters on Si

While there have been numerous demonstrations of planar growth of III-V materials on Si substrates, growing III-V nanostructures directly on Si is not a trivial task. In this project, we aim to demonstrate the direct growth of InP/InAsP light-emitting nanostructures on Si substrates by engineering the III-V/Si interfacial energy. 

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

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

Bottom-up fabrication of lasers via epitaxial growth has been emerging as a promising alternative to the conventional top-down fabrication methods. In this project, we aim to demonstrate electrically-injected lasing in InP/InAsP multi-quantum well micro-ring cavities that are grown by the selective area epitaxy technique.

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

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

In this project, we aim to demonstrate lasing in a bottom-up metasurface device supporting a perturbed symmetry-protected, quasi-BIC mode. The unit cell of the metasurface consists of a pair of InP nanosheet structures that are grown with the selective area epitaxy technique. 

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

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, Prof Andrey Miroshnichenko

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

Quantum Science and Technology

Integrated quantum photonics

The goal of the project is to understand new physical phenomena arising from quantum and nonlinear optical integration. In the future this research may open doors to new types of computers and simulators with information capacity exceeding the number of elementary particles in the entire universe.

Prof Andrey Sukhorukov, Dr Jinyong Ma, Dr Jihua Zhang, Prof Dragomir Neshev

Synthetic multi-dimensional photonics

This project goal is to investigate, theoretically and experimentally, photonic systems with synthetic dimensionality exceeding the three spatial dimensions, and reveal new opportunities for applications in optical signal switching and sensing in classical and quantum photonics.

Prof Andrey Sukhorukov, Dr Jihua Zhang

Quantum photonics with nanostructured metasurfaces

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

Dr Jinyong Ma, Prof Andrey Sukhorukov, Dr Jihua Zhang

Theoretical Physics

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, Prof Andrey Miroshnichenko

Topological and Structural Science

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