Multifunctional 2D materials for sustainable energy applications. This project seeks to explore the great potential of novel graphene-like two dimensional (2-D) materials for energy applications. 2-D materials, which possess atomic or molecular thickness and infinite planar lengths, are regarded as a building block for many applications due to their unique nanostructures, electronic and mechanical properties. This project is focused on the design and exploration of layered two-dimensional artifi ....Multifunctional 2D materials for sustainable energy applications. This project seeks to explore the great potential of novel graphene-like two dimensional (2-D) materials for energy applications. 2-D materials, which possess atomic or molecular thickness and infinite planar lengths, are regarded as a building block for many applications due to their unique nanostructures, electronic and mechanical properties. This project is focused on the design and exploration of layered two-dimensional artificial graphene and graphene analogues with ‘on-demand’ properties to exploit advanced energy applications. There is now a pressing need to integrate graphene sheets into multidimensional and multifunctional systems with spatially well-defined configurations, and integrated systems with a controllable structure and predictable performance. Project outcomes may lead to next-generation devices in energy storage and other applications.Read moreRead less
2D heterostructures with ultrafast interlayer transport for energy devices. This project aims to design novel 2D heterostructures with ultrafast interlayer transport properties and to modulate the associated optical, electric, catalytic, surface and storage properties by using a combination of experimental and computational approaches for sustainable energy applications, such as fuel generation and energy conversion and storage devices. This project expects to generate new knowledge in materials ....2D heterostructures with ultrafast interlayer transport for energy devices. This project aims to design novel 2D heterostructures with ultrafast interlayer transport properties and to modulate the associated optical, electric, catalytic, surface and storage properties by using a combination of experimental and computational approaches for sustainable energy applications, such as fuel generation and energy conversion and storage devices. This project expects to generate new knowledge in materials science and nanotechnology and make fundamental breakthroughs in new sustainable energy technologies. The outcomes of this project will facilitate the development of novel materials and low-cost sustainable energy in Australia with access to an enormous global market. Read moreRead less
On-demand 3D polymer scaffolds for directed stem cell differentiation. The project will develop new polymer gels that can be sculpted into shapes, representing tissues and organs. This 3D scaffold will provide a surface with biological signals to create functional tissues from stem cells. The approach will create engineered intestinal tissue with great promise to increase the survival rates of colon cancer patients.
Bio-inspired two-dimensional nanomaterials for sustainable applications. This project aims to design multifunctional nanomaterials in the form of two-dimensional (2D) structures or architectures with targeted extraordinary bio-mimicking functions for sustainable development and energy applications by learning the best from nature. Millions of years of evolution and natural selection have turned the biological world into an effective materials-development laboratory. The project expects to enhanc ....Bio-inspired two-dimensional nanomaterials for sustainable applications. This project aims to design multifunctional nanomaterials in the form of two-dimensional (2D) structures or architectures with targeted extraordinary bio-mimicking functions for sustainable development and energy applications by learning the best from nature. Millions of years of evolution and natural selection have turned the biological world into an effective materials-development laboratory. The project expects to enhance research and innovation in materials science, nanotechnology, and biological science, and lead to advances in the chemical industry and sustainable environmental and energy applications in Australia. Read moreRead less
Controllable Synthesis of Defects in Catalysts for Electrocatalysis . This project aims to address the most critical issue of electrocatalysis: identification of active sites for carbon-based metal free catalysts (CMFCs). Through the development of new methodologies, this proposal will, for the first time, controllably synthesise the vacancy defects that are the major active sites for CMFCs. The expected outcomes from this project include in-depth understanding of the fundamentals of electrocata ....Controllable Synthesis of Defects in Catalysts for Electrocatalysis . This project aims to address the most critical issue of electrocatalysis: identification of active sites for carbon-based metal free catalysts (CMFCs). Through the development of new methodologies, this proposal will, for the first time, controllably synthesise the vacancy defects that are the major active sites for CMFCs. The expected outcomes from this project include in-depth understanding of the fundamentals of electrocatalysis: the reactivity of active sites and the catalytic performance with the number of active sites; which will not only significantly advance knowledge but also achieve breakthrough technologies that greatly benefit to the society and economy both for Australia and worldwide.Read moreRead less
Mimicking the perivascular niche with boronolectin-based biomaterials. This project aims to address roadblocks in perivascular stem cell manufacturing by discovering novel mechanisms and materials that improve cell quality outcomes during extended culture. An innovative, interdisciplinary approach to biomaterials discovery, combining live cell-based screening of cell surface glycans, bio-inspired materials design and synthesis, and niche mimicry, will enable the discovery of cell surface glycan- ....Mimicking the perivascular niche with boronolectin-based biomaterials. This project aims to address roadblocks in perivascular stem cell manufacturing by discovering novel mechanisms and materials that improve cell quality outcomes during extended culture. An innovative, interdisciplinary approach to biomaterials discovery, combining live cell-based screening of cell surface glycans, bio-inspired materials design and synthesis, and niche mimicry, will enable the discovery of cell surface glycan-mediated interactions that support long-term expansion and potency maintenance, and synthetic biomaterials that can mimic them. Significant benefits for stem cell researchers, manufacturers and end users are expected from the project and the application of this scalable biomaterial platform.Read moreRead less
Soft materials containing hierarchy via 3D sacrificial micro-moulding. The project seeks to develop sophisticated new polymeric materials and devices not possible using current manufacturing techniques. Biomaterials based on hydrogels are ideal substrates for synthetic extra-cellular matrices due to their high water content. However, one of the challenges hindering the use of hydrogels is reproducing the transport properties found in natural tissue with hierarchical features such as vascularisat ....Soft materials containing hierarchy via 3D sacrificial micro-moulding. The project seeks to develop sophisticated new polymeric materials and devices not possible using current manufacturing techniques. Biomaterials based on hydrogels are ideal substrates for synthetic extra-cellular matrices due to their high water content. However, one of the challenges hindering the use of hydrogels is reproducing the transport properties found in natural tissue with hierarchical features such as vascularisation. To address this, the project plans to develop a 3D moulding process for generating soft materials containing precise channels decorated with defined molecules. Intended outcomes include a fundamental understanding of the 3D moulding process, and new polymers and advanced tools for bioengineers for future applications such as tissue transplants, cell guides for treating spinal cord injuries, soft robotics and microfluidic devices to study cancer metastasis. Read moreRead less
Green synthesis of organometal perovskite solar cells. This project aims to understand the mechanism that governs the formation and crystallisation process of organic-inorganic lead halide perovskite films from non-toxic, environmentally friendly, protic ionic liquids. The project will develop new ionic liquid solvent systems that deliver appropriate morphology, and electrical and optical properties to fabricate high performance perovskite solar cells using environmentally friendly, low-toxicity ....Green synthesis of organometal perovskite solar cells. This project aims to understand the mechanism that governs the formation and crystallisation process of organic-inorganic lead halide perovskite films from non-toxic, environmentally friendly, protic ionic liquids. The project will develop new ionic liquid solvent systems that deliver appropriate morphology, and electrical and optical properties to fabricate high performance perovskite solar cells using environmentally friendly, low-toxicity processes. Successful achievement of the outcomes will enable environmentally-friendly, industrial scale processing of perovskite materials, placing Australia at the forefront of organometallic perovskite materials processing with applications in renewable energy and other electro-optical applications.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL170100014
Funder
Australian Research Council
Funding Amount
$3,275,680.00
Summary
Light-Induced chemical modularity: a new frontier in macromolecular design. This project aims to develop powerful light-driven chemistries for the modular construction of advanced macromolecular materials. The expected outcome is a versatile, light-based precision macromolecular synthetic technology platform, enabling critical advances in soft matter material design and synthesis, ranging from selectivity control of chemical reactions and information-coded and biomimetic light-responsive macromo ....Light-Induced chemical modularity: a new frontier in macromolecular design. This project aims to develop powerful light-driven chemistries for the modular construction of advanced macromolecular materials. The expected outcome is a versatile, light-based precision macromolecular synthetic technology platform, enabling critical advances in soft matter material design and synthesis, ranging from selectivity control of chemical reactions and information-coded and biomimetic light-responsive macromolecules to advanced functional photoresists for 3D laser lithography as well as materials that self-report structural transformations by light or are reprogrammable in their properties by photonic fields. Harnessing the power of light as a precision tool for the construction of advanced macromolecular materials will provide technology outcomes for Australian manufacturing industries from electronics to health. This includes laser-driven 3D printing technology at the nano-level, light-adaptive smart reprogrammable coatings and materials, synthetic proteins responsive to light as well as tailor-made single cell niches.Read moreRead less