Hybrid cathode for low temperature solid oxide fuel cells. This project aims to develop molten carbonate-perovskite hybrid cathode materials for low temperature solid oxide fuel cells (LT-SOFCs) possessing both high catalytic activity towards oxygen reduction reaction (ORR) and high tolerance to carbon dioxide poisoning. Carbon dioxide in air can poison nearly all the perovskite cathode materials developed for LT-SOFCs (below 600 degrees C) so far. These materials will not be practically useful ....Hybrid cathode for low temperature solid oxide fuel cells. This project aims to develop molten carbonate-perovskite hybrid cathode materials for low temperature solid oxide fuel cells (LT-SOFCs) possessing both high catalytic activity towards oxygen reduction reaction (ORR) and high tolerance to carbon dioxide poisoning. Carbon dioxide in air can poison nearly all the perovskite cathode materials developed for LT-SOFCs (below 600 degrees C) so far. These materials will not be practically useful until carbon dioxide poisoning can be prevented. This project expects to make these LT-SOFC cathode materials commercially viable, solving a problem for the widespread use of low temperature solid oxide fuel cells.Read moreRead less
High Performance Anode for Direct Ammonia Solid Oxide Fuel Cells. Solid oxygen fuel cells are a clean energy generation device with very high energy efficiency and if with hydrogen as fuel, the emission is zero. However, the utilisation of hydrogen is limited by on-board storage. Ammonia is a promising hydrogen carrier and can be directly fed to solid oxide fuel cells without fuel storage problem, and the products are just hydrogen and nitrogen. For direct ammonia solid oxide fuel cells, the key ....High Performance Anode for Direct Ammonia Solid Oxide Fuel Cells. Solid oxygen fuel cells are a clean energy generation device with very high energy efficiency and if with hydrogen as fuel, the emission is zero. However, the utilisation of hydrogen is limited by on-board storage. Ammonia is a promising hydrogen carrier and can be directly fed to solid oxide fuel cells without fuel storage problem, and the products are just hydrogen and nitrogen. For direct ammonia solid oxide fuel cells, the key challenge is the anode. This project aims to develop a high performance anode for direct ammonia solid oxide fuel cells with both high activity and high stability at low temperature (below 600 degree C), thus addressing a key issue to make the direct ammonia solid oxide fuel cells commercially viable.Read moreRead less
Composites for thermal expansion matched oxygen electrodes. This project aims to develop high performance composite oxygen electrodes by using both negative thermal expansion materials and electrolyte materials to tailor the thermal expansion and activities of the perovskite-based electrodes for use in reduced temperature solid oxide cells. Such composite electrodes will show highly matched thermal expansion with electrolyte without sacrificing high activity at reduced temperatures. This project ....Composites for thermal expansion matched oxygen electrodes. This project aims to develop high performance composite oxygen electrodes by using both negative thermal expansion materials and electrolyte materials to tailor the thermal expansion and activities of the perovskite-based electrodes for use in reduced temperature solid oxide cells. Such composite electrodes will show highly matched thermal expansion with electrolyte without sacrificing high activity at reduced temperatures. This project seeks to address an important practical issue in the operation of solid oxide power cells - thermal expansion compatibility, which causes poor efficiency outside a narrow temperature band.Read moreRead less
Nano/micro grinding mechanisms and technologies for brittle materials. The successful completion of the project will solve a long standing problem, that is, the ductile removal mechanism in the machining of brittle materials and create a strong knowledge base for the development of technology and characterization techniques for nano/micro mechanical machining of such materials. This will strengthen UWA's research capability and international competitiveness in the field of nano/micro manufacturi ....Nano/micro grinding mechanisms and technologies for brittle materials. The successful completion of the project will solve a long standing problem, that is, the ductile removal mechanism in the machining of brittle materials and create a strong knowledge base for the development of technology and characterization techniques for nano/micro mechanical machining of such materials. This will strengthen UWA's research capability and international competitiveness in the field of nano/micro manufacturing. The pragmatic grinding technology developed for fabricating micro aspherical mould inserts and lenses will directly benefit the optics/photonics, microelectronics and biomedical industries in Australia. This will help to position Australia in the forefront of emerging industries in the new millenniumRead moreRead less
Effect of Chemo-Mechanical Grinding on Surface Integrity of Single Crystal Silicon Substrates. Silicon substrates or wafers are extensively used in electronic and optic/photonic industries. A long-time standing problem in silicon wafer machining is the surface and subsurface damage induced by machining. This may significantly affect the mechanical, optical and electronic characteristics of wafer-based components. The issue becomes increasingly more critical as the application of silicon wafers i ....Effect of Chemo-Mechanical Grinding on Surface Integrity of Single Crystal Silicon Substrates. Silicon substrates or wafers are extensively used in electronic and optic/photonic industries. A long-time standing problem in silicon wafer machining is the surface and subsurface damage induced by machining. This may significantly affect the mechanical, optical and electronic characteristics of wafer-based components. The issue becomes increasingly more critical as the application of silicon wafers is extending further as structural components. The research outcomes will contribute an improved understanding of Chemo Mechanical Grinding process and help to develop innovative technologies for silicon industries.Read moreRead less
Quantification of airborne engineered nanoparticles: developing a scientific framework to inform their regulation and control. Despite the presence of airborne engineered nanoparticles in many commercial/research facilities, there are no established methods for their detection/characterisation. This work aims to develop a foundation for the quantitative assessment of airborne engineered nanoparticles, which is critical for controlling exposure and minimising health risks.
Detection, characteristics and dynamics of airborne engineered nanoparticles for human exposure assessment. Recent advances in nanotechnology have led to questions about the safety of airborne engineered nanoparticles in commercial and research facilities. This project aims to develop an understanding of nanoparticle emission and behaviour in the air, which is needed to control workplace exposure to these particles and minimise the risk to human health.
Industrial Transformation Research Hubs - Grant ID: IH150100003
Funder
Australian Research Council
Funding Amount
$2,611,346.00
Summary
ARC Research Hub for Graphene Enabled Industry Transformation. ARC Research Hub for Graphene Enabled Industry Transformation. This research hub aims to provide the advanced materials industry with innovative solutions to tackle critical and complex challenges of national significance. The hub intends to leverage substantial existing and new investments to overcome fundamental scientific barriers and develop fit-for-purpose graphene products with and for its partners. Advanced materials, particul ....ARC Research Hub for Graphene Enabled Industry Transformation. ARC Research Hub for Graphene Enabled Industry Transformation. This research hub aims to provide the advanced materials industry with innovative solutions to tackle critical and complex challenges of national significance. The hub intends to leverage substantial existing and new investments to overcome fundamental scientific barriers and develop fit-for-purpose graphene products with and for its partners. Advanced materials, particularly graphene, are now considered promising for maintaining competitive advantages for industrial transformational progress; and advanced industries to drive prosperity where innovation underpins business to thrive globally. The anticipated impacts are long-term economic prosperity and growth.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH210100025
Funder
Australian Research Council
Funding Amount
$4,379,165.00
Summary
ARC Research Hub for Advanced Manufacturing with 2D Materials (AM2D). Australia holds large resources of critical 2D minerals – key enablers of several existing and emerging technologies in Energy Storage, Purification and Printed Electronics. The AM2D hub aims to provide a sophisticated environment for researchers and an industrial translation platform for manufacturers; a hub where leading academics, bright students, and industry partners come together to learn, apply, collaborate, innovate, a ....ARC Research Hub for Advanced Manufacturing with 2D Materials (AM2D). Australia holds large resources of critical 2D minerals – key enablers of several existing and emerging technologies in Energy Storage, Purification and Printed Electronics. The AM2D hub aims to provide a sophisticated environment for researchers and an industrial translation platform for manufacturers; a hub where leading academics, bright students, and industry partners come together to learn, apply, collaborate, innovate, and deliver industry transformation in advanced manufacturing. Anticipated outcomes include the transformation of newly discovered materials into globally traded, high-value 2D products, enabling Australian industries to capture more wealth and jobs from this large and growing market.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100174
Funder
Australian Research Council
Funding Amount
$425,000.00
Summary
X-Ray Nanolithography Facility: Towards the ultimate resolution. This Project aims to address the need for precise and scalable nanoscale fabrication by establishing a synchrotron-based X-Ray Nanolithography Facility. This Project expects to generate new knowledge in the areas of advanced manufacturing and nanotechnology using an innovative approach that combines coherent lithography and coherent imaging metrology. Expected outcomes of this project include an internationally unique, nationally ....X-Ray Nanolithography Facility: Towards the ultimate resolution. This Project aims to address the need for precise and scalable nanoscale fabrication by establishing a synchrotron-based X-Ray Nanolithography Facility. This Project expects to generate new knowledge in the areas of advanced manufacturing and nanotechnology using an innovative approach that combines coherent lithography and coherent imaging metrology. Expected outcomes of this project include an internationally unique, nationally accessible capability for manufacturing at the nanoscale and for industry-driven collaborative research. This should provide significant benefits across fields that aim to harness the unique properties of engineered nanomaterials to greatly enhance the technologies required to solve global challenges.Read moreRead less