The Australian Research Data Commons (ARDC) invites you to participate in a short survey about your
interaction with the ARDC and use of our national research infrastructure and services. The survey will take
approximately 5 minutes and is anonymous. It’s open to anyone who uses our digital research infrastructure
services including Reasearch Link Australia.
We will use the information you provide to improve the national research infrastructure and services we
deliver and to report on user satisfaction to the Australian Government’s National Collaborative Research
Infrastructure Strategy (NCRIS) program.
Please take a few minutes to provide your input. The survey closes COB Friday 29 May 2026.
Complete the 5 min survey now by clicking on the link below.
Swift heavy ion induced nano-porous antimony-based semiconductors. This project aims to study the fabrication and application of nano-porous antimony based semiconductors prepared by high-energy ion irradiation. Using a unique combination of synchrotron and laboratory- based analytical techniques as well as computer simulations, the project expects to identify the physical mechanisms for porous structure formation and exploit the materials for application in thermoelectric and thermo-photovoltai ....Swift heavy ion induced nano-porous antimony-based semiconductors. This project aims to study the fabrication and application of nano-porous antimony based semiconductors prepared by high-energy ion irradiation. Using a unique combination of synchrotron and laboratory- based analytical techniques as well as computer simulations, the project expects to identify the physical mechanisms for porous structure formation and exploit the materials for application in thermoelectric and thermo-photovoltaic devices. Expected outcomes of the project include fabrication processes compatible with current device fabrication methodologies that should enable rapid integration of the materials into advanced device applications. Significant benefits should result from novel applications of the technologies such as energy harvesting and sensor devices.Read moreRead less
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. It is expected that this project will mak ....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. It is expected that this project will make significant contributions to the development of next generation high performance, fast speed, small size and low cost infrared photodetector technology platform enabling numerous emerging fields in modern transportation, communication, quantum computation and information processing to revolutionise our life and society.Read moreRead less
Generating Highly Entangled Photons from Nonlinear Monolayer Domes. This project aims to investigate novel monolayer domes for the development of high-performance quantum photon sources. This research expects to expand our understanding of fundamental physics of photon pair generation in nonlinear optical materials. Such monolayer domes have ultra-high optical nonlinearity, which gives rise to strong light-matter interactions and enables high-efficiency photon pair generation. The expected outco ....Generating Highly Entangled Photons from Nonlinear Monolayer Domes. This project aims to investigate novel monolayer domes for the development of high-performance quantum photon sources. This research expects to expand our understanding of fundamental physics of photon pair generation in nonlinear optical materials. Such monolayer domes have ultra-high optical nonlinearity, which gives rise to strong light-matter interactions and enables high-efficiency photon pair generation. The expected outcome is demonstration of a prototype light-weight and intense quantum photon source based on novel materials, which can be readily integrated with photonic circuits for quantum communication technologies. This research could strengthen the development of new industries and lead to job creation.Read moreRead less
Probing and harnessing the light-matter interactions in two-dimensional phosphorene. This project aims to investigate phosphorene, a new two-dimensional material, for the development of new optical and electronic devices. Such materials have unique optical and electronic properties due to their flat physical structure, which gives rise to strong interactions between light and matter. The expected outcome of this project will be new kinds of near infrared light emitting diodes, single photon emit ....Probing and harnessing the light-matter interactions in two-dimensional phosphorene. This project aims to investigate phosphorene, a new two-dimensional material, for the development of new optical and electronic devices. Such materials have unique optical and electronic properties due to their flat physical structure, which gives rise to strong interactions between light and matter. The expected outcome of this project will be new kinds of near infrared light emitting diodes, single photon emitters and ground-breaking lasers. These developments will enable the fabrication of new low-power light sources that can integrate with communication technologies now, and quantum communication technologies in the future.Read moreRead less
Unlocking exceptional properties through pressure-induced phase transitions. The aim of this project is to produce novel hybrid boron nitride materials by utilizing advanced green techniques of mechanochemistry and high-pressure methods to achieve a phase transition from hexagonal to wurtzite structure. The development of these materials is critical in tackling contemporary environmental and technological issues, particularly those linked to cooling systems in electronic devices and batteries. T ....Unlocking exceptional properties through pressure-induced phase transitions. The aim of this project is to produce novel hybrid boron nitride materials by utilizing advanced green techniques of mechanochemistry and high-pressure methods to achieve a phase transition from hexagonal to wurtzite structure. The development of these materials is critical in tackling contemporary environmental and technological issues, particularly those linked to cooling systems in electronic devices and batteries. The outcome of this study will be new nanomaterials with exceptional mechanical, thermal, and electronic properties, as well as new insights into mechanical-force induced green chemistry and an environmentally friendly synthesis process, and help with heat management, energy preservation, and advanced manufacturing.Read moreRead less
Harnessing Interlayer Biexcitons in Atomically Thin Heterostructures. This project aims to investigate the generation of high-quality quantum light sources by harnessing interlayer biexcitons in atomically thin heterostructures. This research expects to expand our understanding of fundamental physics of photon pair generation in atomically thin heterostructures. The expected outcome is demonstration of a prototype light-weight and intense quantum photon source based on novel materials, which can ....Harnessing Interlayer Biexcitons in Atomically Thin Heterostructures. This project aims to investigate the generation of high-quality quantum light sources by harnessing interlayer biexcitons in atomically thin heterostructures. This research expects to expand our understanding of fundamental physics of photon pair generation in atomically thin heterostructures. The expected outcome is demonstration of a prototype light-weight and intense quantum photon source based on novel materials, which can be readily integrated with photonic circuits for quantum communication technologies, enbling the developments of light weight portable devices, such as mobile phones, displays, and wearable photonics. This research could strengthen the development of new industries and lead to job creation in Australia. Read moreRead less