New findings in atomic science will revolutionise the fields of material design and nanofabrication. Our research will help lay a solid foundation for the next generation of functional materials and miniaturised devices by restructuring the most fundamental building blocks at the atomic level, with the aim to outperform macroscale materials and/or devices on detection accuracy, energy efficiency, and production efficacy.
Our research directly contributes to the development of a new generation of atomic materials and technologies, which will have a long-lasting impact in the societal and business enterprise landscape of Australia, and worldwide.
We also provide training opportunities to young scientists, research students, and industry, in world-leading nanotechnology.
Materials design at the atomic scale has become so approachable due to the rapid development of computational technologies. This research theme focuses on the application-driven computer-aided materials design (CAMD) with state-of-art computational techniques. Smart design and advanced manufacture need novel high-performance materials, which might not be found in naturally existing materials. CAMD helps to design the materials and guide experimentalists to achieve the design. Large scale computational screening, as a key strength, will be employed to design and identify promising materials for specific applications, particularly for renewable energy and smart manufacture.
- AI powered molecular structure design
- Application-driven computer-aided materials design (CAMD) with state-of-art computational techniques
- Density functional theory (DFT) calculations
- Pre-screened high-performance materials design
- Modify the codes with GPU capacity and develop specialised force field from the DFT calculations
- Identification and realisation of promising new materials with desired material properties
- Data-driven accelerated atomistic computational method
- Efficient on-the-fly characterization schemes
Theme Leader: Professor Feng Wang
Advanced Material Characterisation
The design, synthesis and application of atomic materials require an ability to characterise the materials on the appropriate scale. While techniques such as transmission electron microscopy (TEM) and scanning tunnelling microscopy (STM) have been able to provide atomic level resolution for some time now, it remains challenging to obtain structural and functional information about a range of materials at the 10-10 m scale on a routine basis. To extend these techniques and make them more broadly available requires the combined expertise of physicists, chemists and engineers.
- Atomic level of manipulation and fabrication resolution with high speed and in a large scale for functional atomic devices
- Low energy electron microscopy
- Image surface growth dynamics at real time and high resolution
- Surface analytical characterisation of real plant slurries and applications of synchrotron science
- Surface- and tip-enhanced Raman scattering are surface sensitive analytical techniques
- Microscopic, spectroscopic and optoelectronic characterisation systems
Theme Leader: Professor Paul Stoddart
Deputy Theme Leader: Dr. Changxi Zheng
Novel Structure design/optimisation
This theme focuses on a significant development of a novel topology optimisation technique, in relation to an intelligent design approach of advanced materials and structures. This is currently lacking, with substantial challenges remaining. This theme will develop design approaches and computation tools for engineering advanced materials and structures, which is significant in both fundamental research and applications. The unique competitive advantages include our world-leading research achievements demonstrated by Theme leader, Prof. Huang, in the topology optimisation method and its multidisciplinary applications.
- Extract and characterise the properties or functionalities of complex structures
- Optimise structures so as to achieve desirable properties and functionalities
- Develop multi-disciplinary and multi-physics design tools for creating novel structures
- Realise specific functionalities and/or enhance their performance
- Develop design approaches and computation tools for engineering advanced materials and structures
- Conducting polymer synthesis and device fabrication
- Materials science and catalysis
Theme Leader: Professor Xiaodong Huang
Atomic device fabrication / Prototype and laser 3D nano-printing
In this theme, we aim to develop a unique concept based on tailored laser beams to decode the fundamental link between the amazing properties of atomic materials (including 2D materials), and their atomic bonds, based on Prof. Jia and Dr Lin’s more than 15 years’ of experience in the ultrafast optical field. By tailoring the laser beams, the reaction paths of atomic materials can be controlled at will, leading to the selective removal, rearrangement and production of desired bonds, and thus the realisation of full fundamental manipulation of the atomic scale building blocks of materials. Such atomic materials will have unique optical, electrical or mechanical properties. Based on these properties and the wonderful state-of-the-art research facility and infrastructure at Swinburne, we can construct functional prototypes for specific applications in the areas of energy generation and storage, health and wellbeing, aerospace sensors and optical communications and computing.
- Fabrication of atomaterials, nanomaterials and nanostructures
- Thin film coatings
- Surface analysis
- In vitro and in vivo characterization of materials
- Design, fabrication and characterization of 3D nanostructures
- Optical and electrochemical test and characterization on the atomic or nanometer scale
- Solar energy harvesting pilot production
- Supercapacitor pilot production
Theme Leader: Professor Baohua Jia
Deputy Theme Leader: Dr. Han Lin
Atomic material engineering
One is energy storage materials engineering and the other is to design efficient catalysts for solar fuels. This research theme will advance the fundamental materials sciences and make technological breakthroughs needed to meet the global energy and environmental challenges. The innovation of our technology lies in the use of theoretical guidance and advanced technologies (atomic engineering and defect controlling) to address the energy challenges. Such innovations will enable continuous improvement of these areas or even dramatic breakthroughs that would bring a new landscape for the Australian industry.
- Develop high-performing energy storage materials and devices using atomic engineering methodology
- Determine the structure and property links by corrected advanced microscopy characterisation and transport measurement
- Optimise device design and assembly for cost effectiveness
- Atomic level engineering to achieve selectivity of problems
- Translating practical catalyst materials through to functional devices
Theme Leader: Associate Professor Chenghua Sun
Deputy Theme Leader: Dr. Rosalie Hocking
The focus of this theme is to analyse the demands and problems from our industrial partners and end-users, categorise them according to expertise of CIs and centre's members, logically study the nature of problems and then create appropriate types of projects to the Centre to resolve. Based on the nature of problems and projects, this theme will also coordinate the CIs in activities of leveraging of industry contributions, by applying for funding from governments and foundations, including ARC Linkage programs, CRC, ARENA etc. to support research and/or consultancy projects.
- Collect demands and understand problems from the industry and end-users
- Engage activities with industry partners and other stakeholders
- Analyse the problems logically
- Lead CTAM CIs to develop solutions
- Deliver values to partners
Theme Leader: Professor Alan Lau