Polymer-functionalised nanotubes: controlled formation by self-assembly. This project will develop new structures of nanotubes by combining peptide sequences and synthetic polymers. These nanostructured materials will form the basis of a wide range of technological applications, such as inorganic nanotubes, ion channels, drug carriers, and more broadly in nanotechnology and nanomedicine.
Soft nanotubes for biomedical applications. Nature employs self-assembly of small molecules to build complex materials. This project will mimic natural self-assemblies to design synthetic tubular structures on the nanoscale, and apply these nanostructures to solve problems in the fields of biology and medicine.
Multiblock copolymer synthesis for nano-engineered materials. This project aims to develop methodology for environmentally friendly and industrially applicable synthesis of new types of advanced polymeric materials comprising multiblock copolymers. Polymeric materials play an important role in society with applications from bulk plastics to advanced technological applications. This would enable the creation of advanced materials with specific engineering targets and applications ranging from nan ....Multiblock copolymer synthesis for nano-engineered materials. This project aims to develop methodology for environmentally friendly and industrially applicable synthesis of new types of advanced polymeric materials comprising multiblock copolymers. Polymeric materials play an important role in society with applications from bulk plastics to advanced technological applications. This would enable the creation of advanced materials with specific engineering targets and applications ranging from nanomedicine to materials science.Read moreRead less
Built-in electric field, light co-driven materials for energy and sensing . This project aims to resolve critical, bottleneck issues in the development of photocatalysis and photoelectrochemistry - key technologies towards the realisation of a sustainable carbon-neutral society. This project expects to use an innovative strain-engineering approach establishing a built-in electric field within materials for highly efficient separation and transport of photoexcited carriers. Expected outcomes of t ....Built-in electric field, light co-driven materials for energy and sensing . This project aims to resolve critical, bottleneck issues in the development of photocatalysis and photoelectrochemistry - key technologies towards the realisation of a sustainable carbon-neutral society. This project expects to use an innovative strain-engineering approach establishing a built-in electric field within materials for highly efficient separation and transport of photoexcited carriers. Expected outcomes of this project are to create new, ground-breaking materials and/or nanosystems that overcome intrinsic weakness of conventional semiconductors and significantly improve their photocatalytic and photoelectrochemical performance, for the benefit of the utilisation of solar and light energy in energy, environment and health. Read moreRead less
ARC Centre of Excellence for Electromaterials Science. The ARC Centre of Excellence for Electromaterials Science (ACES) will create next generation electrochemical devices via the precision assembly of nano/micro dimensional components into macroscopic structures. Through the discovery of new materials and structures, and understanding how spatial arrangement in 3D influences chemical, physical and biological properties, ACES will define the cutting edge of Electromaterials Science. The resultin ....ARC Centre of Excellence for Electromaterials Science. The ARC Centre of Excellence for Electromaterials Science (ACES) will create next generation electrochemical devices via the precision assembly of nano/micro dimensional components into macroscopic structures. Through the discovery of new materials and structures, and understanding how spatial arrangement in 3D influences chemical, physical and biological properties, ACES will define the cutting edge of Electromaterials Science. The resulting technology breakthroughs will have a direct impact on some of today's most challenging global problems in clean energy, synthetic biosystems, diagnostics and soft robotics. National benefit to Australia will be realised through the creation of new manufacturing industries.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC170100020
Funder
Australian Research Council
Funding Amount
$3,279,502.00
Summary
ARC Training Centre for the Chemical Industries . The ARC Training Centre for the Chemical Industries will foster a world-class environment of transformative innovative research in Australia’s chemical and advanced manufacturing industry through sustained partnerships with universities. The Centre establish a new industry-led HDR graduate program. The research activities of the Centre aim to improve chemical analytical and manufacturing capabilities, new biopharmaceuticals, enhanced global compe ....ARC Training Centre for the Chemical Industries . The ARC Training Centre for the Chemical Industries will foster a world-class environment of transformative innovative research in Australia’s chemical and advanced manufacturing industry through sustained partnerships with universities. The Centre establish a new industry-led HDR graduate program. The research activities of the Centre aim to improve chemical analytical and manufacturing capabilities, new biopharmaceuticals, enhanced global competitive advantages, and long-term growth and intellectual property development in the chemistry industry. Other national benefits include up-skilled, workplace-ready graduates with experience in conducting industry-focused research.Read moreRead less