Engineered nanoassmblies for energy conversion. This research will lead to development of clean energy technology that can compete with the traditional energy sources without subsidies, and facilitate long-term solution to the energy crisis and global warming. It will also bring significant benefit to Australian industries and economy and assist achievement of renewable energy target.
Polymer nanoparticles and their assembled supracolloidal monolithic structures for applications in separation science. This project will generate new polymeric materials that will improve the analysis of complex samples. This will be applied in a wide range of areas of national importance including: pharmaceutical analysis and drug discovery; environmental, clinical and forensic analysis; and energy generation and foods.
Design and synthesis of operating molecular machines and solution and solid-state devices. This project involves the construction of machines and other devices engineered at the molecular level, which therefore offer a greater degree of miniaturisation and sophistication than their macro-engineered counterparts. The work is expected to provide fundamental advances in nanotechnology and underpin new industries based on advanced materials.
Responsive nanoporous organic cages. This project will generate advanced materials that are constructed from functional nanoscale building blocks. The general design principles developed in this work will be utilised to synthesise a nanoporous adsorbent system that is able to self regulate its physical properties through dynamic structural responses to its environment.
Discovery Early Career Researcher Award - Grant ID: DE220100163
Funder
Australian Research Council
Funding Amount
$411,000.00
Summary
Harnessing dynamic materials to produce better heterogeneous catalysts. This project aims to investigate an emerging class of catalysts featuring dynamic reaction sites using innovative computational chemistry methods. The capability of traditional materials has reached a performance status quo for many catalytic reactions. Dynamic materials may unlock a new dimension in catalyst design; however, their influence on reactivity is unclear, and the combination of materials and dynamics represents a ....Harnessing dynamic materials to produce better heterogeneous catalysts. This project aims to investigate an emerging class of catalysts featuring dynamic reaction sites using innovative computational chemistry methods. The capability of traditional materials has reached a performance status quo for many catalytic reactions. Dynamic materials may unlock a new dimension in catalyst design; however, their influence on reactivity is unclear, and the combination of materials and dynamics represents an immense parameter space. This project expects to provide a comprehensive framework for understanding dynamic catalytic processes. Expected outcomes of this project include the identification of specific materials and dynamics that achieve extraordinary efficiency for the benefit of sustainable chemical production.Read moreRead less
Designing and Building Novel 2D Hybrid Materials. The aim of this project is to use computational and experimental techniques to discover and fabricate new hybrid materials. Single-layer (2-D) materials like graphene have gained prominence and new ones are constantly being reported. Hybrid materials built from combinations of 2-D layers are appearing but progress is slow. This project is designed to increase the rate of discovery and fabrication of hybrids. The outcome would be an extensive data ....Designing and Building Novel 2D Hybrid Materials. The aim of this project is to use computational and experimental techniques to discover and fabricate new hybrid materials. Single-layer (2-D) materials like graphene have gained prominence and new ones are constantly being reported. Hybrid materials built from combinations of 2-D layers are appearing but progress is slow. This project is designed to increase the rate of discovery and fabrication of hybrids. The outcome would be an extensive database of materials properties, clear direction on how to control material properties, and manufacturing protocols to build a wide range of new materials.Read moreRead less
Special Research Initiatives - Grant ID: SR0354640
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Young Investigators Network on Next Generation Electronic Devices. This initiative will build an active, dynamic and strongly interdisciplinary network of young Australian scientists (most awarded their Ph.D. after 1985) working on the development of innovative electronic devices - a national research priority area with enormous economic and technological opportunity. The network will enable a nationally coordinated, internationally competitive approach that capitalizes on untapped opportunitie ....Young Investigators Network on Next Generation Electronic Devices. This initiative will build an active, dynamic and strongly interdisciplinary network of young Australian scientists (most awarded their Ph.D. after 1985) working on the development of innovative electronic devices - a national research priority area with enormous economic and technological opportunity. The network will enable a nationally coordinated, internationally competitive approach that capitalizes on untapped opportunities, utilises existing/emerging Australian expertise and develops strong supporting links with similar networks overseas. The initiative will produce a public showcase of Australian strengths and opportunities in this field, and enable stronger collaborations and cooperative logistics management through the development of a dedicated network management website.Read moreRead less