Photochemical Design of Microstructured Aerospace Materials. Commercial aviation and shipping spend over US$300 billion on fuel and emit almost 3 billion tonnes of carbon dioxide annually at an enormous environmental cost. This project will provide the material chemistry innovation basis for the production of drag reduction surfaces that can be applied to enable a more effective airflow over an aircraft, thus reducing fuel consumption. Critically, the material design approach will not only deliv ....Photochemical Design of Microstructured Aerospace Materials. Commercial aviation and shipping spend over US$300 billion on fuel and emit almost 3 billion tonnes of carbon dioxide annually at an enormous environmental cost. This project will provide the material chemistry innovation basis for the production of drag reduction surfaces that can be applied to enable a more effective airflow over an aircraft, thus reducing fuel consumption. Critically, the material design approach will not only deliver a high performance coating for the production of drag reduction surfaces, but allow these surfaces to be tailored to specific application profiles including UV resistance and anti-fouling properties. The project will place an Australian company at the forefront of drag reduction technologyRead moreRead less
Precision-built dynamic and functional polymer vesicles. The project aims to create new precision-built polymer vesicles with controlled size, stability, functionality and environmental responsiveness to mimic some of the key dynamic functions of the cell. The project expects to generate new knowledge on the dynamic interplay between the polymer and its bilayer including on-demand activated polymerisations and reactions, logic gates and in situ sensors. Expected outcomes of this project include ....Precision-built dynamic and functional polymer vesicles. The project aims to create new precision-built polymer vesicles with controlled size, stability, functionality and environmental responsiveness to mimic some of the key dynamic functions of the cell. The project expects to generate new knowledge on the dynamic interplay between the polymer and its bilayer including on-demand activated polymerisations and reactions, logic gates and in situ sensors. Expected outcomes of this project include new synthetic polymer techniques and new quantitative insights into the role of compartmentalisation on chemical reactions and polymerisations. This project will provide fundamental knowledge on bio/polymer vesicles with great potential to advance the polymer industry in Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101096
Funder
Australian Research Council
Funding Amount
$427,098.00
Summary
Programming Polymer Function via Ring-opening Polymerisation of Peptides. The project aims to set the foundation of a class of intelligent polymers, whose structure and function – including catalytic activity and biodegradability – can be readily programmed. In contrast to well-established radical polymerization techniques leading to all-carbon based backbones, the outlined research will develop technologies to incorporate short peptides into the backbones of synthetic polymers. The syntheticall ....Programming Polymer Function via Ring-opening Polymerisation of Peptides. The project aims to set the foundation of a class of intelligent polymers, whose structure and function – including catalytic activity and biodegradability – can be readily programmed. In contrast to well-established radical polymerization techniques leading to all-carbon based backbones, the outlined research will develop technologies to incorporate short peptides into the backbones of synthetic polymers. The synthetically adjustable amino acid sequence of the main chain embedded peptides will translate into the structure and function of the modular polymer. The DECRA will deliver unprecedented access towards tailor-made mechanical properties, catalytic activity and biodegradability of polymeric materials.Read moreRead less