Discovery Early Career Researcher Award - Grant ID: DE190101152
Funder
Australian Research Council
Funding Amount
$404,000.00
Summary
Micro/nano-mechanical testing methodologies for interfacial adhesion. This project aims to develop reliable approaches for measuring the toughness of a variety of metal/polymer interfaces integral to contemporary flexible devices. Adhesion between metal thin film conductors and polymer substrates is a critical factor influencing the reliability of the emerging polymer-based flexible electronics. This project will develop new methodologies for understanding the behaviour of these metal/polymer in ....Micro/nano-mechanical testing methodologies for interfacial adhesion. This project aims to develop reliable approaches for measuring the toughness of a variety of metal/polymer interfaces integral to contemporary flexible devices. Adhesion between metal thin film conductors and polymer substrates is a critical factor influencing the reliability of the emerging polymer-based flexible electronics. This project will develop new methodologies for understanding the behaviour of these metal/polymer interfaces. This project will be a crucial enabler to accelerating the development of new flexible microelectronic technologies, from solar panels to electronic skin. This innovation will enable Australia to maintain an important connection to the rapidly-evolving international microelectronic industry and add significant value to Australian manufacturing industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102784
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Water-swellable rubber with nanoparticle-enabled super capacity as smart water-leakage sealant. A novel water-swellable rubber (WSR) sealant with continuous hydrophobic phase and isolated hydrophilic phase is developed for stopping water leakage from gaps and cracks. Nanoparticle-enabled blocks and network channels in rubber matrix effectively improve the integrity and capability of WSR as smart water-leakage sealants in various applications.
Effect of processing on microstructure of 'Biocrete' organo-mortar. 'Biocrete' is a novel organo-mortar whose composition differs substantially from conventional Portland cement based polymer mortars. It is a relatively new product with significant commercial potential because of its acid resistance and ease of application. However, the microstructure of this material is extremely complex and not well understood nor is the way the microstructure develops during the processing and application of ....Effect of processing on microstructure of 'Biocrete' organo-mortar. 'Biocrete' is a novel organo-mortar whose composition differs substantially from conventional Portland cement based polymer mortars. It is a relatively new product with significant commercial potential because of its acid resistance and ease of application. However, the microstructure of this material is extremely complex and not well understood nor is the way the microstructure develops during the processing and application of the material known. This project will use advanced materials characterisation methods to elucidate the microstructure and to quantify the effects of processing parameters on the microstructure. Such information is critical for further formulation and application development in important areas such as sewer relining.Read moreRead less
Optimising paint adhesion to polymers. The Australian automotive export market (vehicles, parts, engines) is worth approximately $4,500 million p.a. and is a major employer in many areas. A reliable, cheap and efficient method for preparing polymer surfaces for painting will significantly benefit that market. The ability to manufacture quality, cheaper, lightweight parts improves the competitiveness of the local automotive industry. More importantly, a technology for production of cheap, high qu ....Optimising paint adhesion to polymers. The Australian automotive export market (vehicles, parts, engines) is worth approximately $4,500 million p.a. and is a major employer in many areas. A reliable, cheap and efficient method for preparing polymer surfaces for painting will significantly benefit that market. The ability to manufacture quality, cheaper, lightweight parts improves the competitiveness of the local automotive industry. More importantly, a technology for production of cheap, high quality painted polymer surfaces vastly improves the competitiveness of local component manufacturers who supply to international vehicle manufacturers. This project falls under the National Research Priority Area 'Frontier Technologies for Building and Transforming Australian Industries'.Read moreRead less
Molecular modelling of the structure and mechanical properties of clay-based polymer nanocomposites. Nanotechnology is one of the most rapidly growing areas in the 21st century. Its world market is expected to reach US$2.6 trillions in 2014, valued at 15% of global manufacturing output. The use of clay nanofillers as polymer reinforcement is an emerging cutting-edge research and of paramount importance in Australia in view of its heavy dependence on mineral industries. The project will tackle th ....Molecular modelling of the structure and mechanical properties of clay-based polymer nanocomposites. Nanotechnology is one of the most rapidly growing areas in the 21st century. Its world market is expected to reach US$2.6 trillions in 2014, valued at 15% of global manufacturing output. The use of clay nanofillers as polymer reinforcement is an emerging cutting-edge research and of paramount importance in Australia in view of its heavy dependence on mineral industries. The project will tackle the core problems in this field. The research outcomes will lead to highly value-added mineral products and better process control. Furthermore, the application of polymer nanocomposites in automotive and packaging industries will significantly decrease energy consumption and CO2 emission, and increase the shelf-life for food and beverage. Read moreRead less
An innovative approach to fabricate thermally stable polymer/layered silicate nanocomposites. By fully taking advantage of excellent affinity of water with polar layered silicate and polar polymer, an innovative approach to fabricate thermally stable polymer/layered silicate nanocomposites via melt extrusion with the aid of water/water vapour will be developed. In this process, the pristine layered silicate will be directly exfoliated into individual layers with nanometer thickness and high aspe ....An innovative approach to fabricate thermally stable polymer/layered silicate nanocomposites. By fully taking advantage of excellent affinity of water with polar layered silicate and polar polymer, an innovative approach to fabricate thermally stable polymer/layered silicate nanocomposites via melt extrusion with the aid of water/water vapour will be developed. In this process, the pristine layered silicate will be directly exfoliated into individual layers with nanometer thickness and high aspect ratio, and uniformly dispersed in a polymer matrix. This novel approach is environmentally benign and cost-effective since no alkyl ammonium surfactants are required. The resultant nanocomposites will exhibit excellent barrier properties, high thermal stability, environmental durability and superior mechanical properties. These qualities make them very attractive for many applications in the automotive and packaging industries.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453480
Funder
Australian Research Council
Funding Amount
$236,899.00
Summary
Nanostructured Polymer Processing Network. The Nanostructured Polymer Processing Network will promote the understanding and manipulation of the processing of novel nanostructured plastic materials. High technology, online polymer processing equipment will be sought that will enable the design of nanostructured polymers via a range of techniques including insitu polymerisation, nanocomposites and polymer blending which are ideal for designing high value nanostructured polymers that are tailored f ....Nanostructured Polymer Processing Network. The Nanostructured Polymer Processing Network will promote the understanding and manipulation of the processing of novel nanostructured plastic materials. High technology, online polymer processing equipment will be sought that will enable the design of nanostructured polymers via a range of techniques including insitu polymerisation, nanocomposites and polymer blending which are ideal for designing high value nanostructured polymers that are tailored for high performance applications. The equipment in this proposal, when combined with existing leading edge polymer characterisation and analysis equipment, will provide a Network with international state-of-the-art equipment that will fast track the success of integrated research projects across the sites.Read moreRead less
Damage micromechanisms in alumina hybrid bilayers with graded interfaces. This project proposes a new design concept for high performance alumina hybrids with graded interfaces. The key to this process is the incorporation of thin graded interfaces between an outer homogeneous alumina layer for strength, hardness and wear resistance, and an inner heterogeneous alumina hybrid layer for damage tolerance. The project will explore unresolved issues concerning the effect of graded interfaces on the f ....Damage micromechanisms in alumina hybrid bilayers with graded interfaces. This project proposes a new design concept for high performance alumina hybrids with graded interfaces. The key to this process is the incorporation of thin graded interfaces between an outer homogeneous alumina layer for strength, hardness and wear resistance, and an inner heterogeneous alumina hybrid layer for damage tolerance. The project will explore unresolved issues concerning the effect of graded interfaces on the failure micromechanisms. Advances in this area will provide new strategy or insights for designing novel next generation layered materials.Read moreRead less