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formulated and executed in the School of Civil and Mechanical Engineering. Curtin University has the academic expertise to execute the computational modelling using computational fluid dynamics and advanced
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engineering strategies to modify the electrodes for stable and efficient ammonia electrosynthesis, and to address the underlying structure-property relationships. Objectives The primary objective
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ceramic fuel cells (PCFCs) have emerged as a forefront electricity generation technology to efficiently convert chemical energy into electricity with zero carbon emissions. In contrast to proton exchange
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(PM10, PM2.5, PM1), it is crucial to understand their sources and distribution patterns to develop effective control measures. The project will leverage advanced sensor technology and computational
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, open up a new avenue towards the next generation of lighting and display devices, and foster early-career researchers in the fields of materials chemistry, electronic devices and energy technologies
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, nanoparticles-modified perovskite oxides which can tackle all the above challenges. By rational materials engineering, this project aims to realise both thermochemical energy storage and greenhouse gas upgrading
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Group (HSRG) situated in the School of Electrical Engineering, Computing and Mathematical Sciences (EECMS) at Curtin University, which is equipped with an array of world-class research equipment and
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chemical reactions is a critical area of research in geosciences and engineering. Developing these areas will allow us to model and predict complex phenomena occurring within fractured rock formations, with
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AGGLOMERATION -Project 1 We are developing an ultrafast agglomeration technology to separate hydrophobic particles, using a novel formulation that reduces the oil consumption by up to 15-fold. The agglomeration
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by offering a safer and more sustainable alternative to pressure oxidation and cyanide leaching. The enrolling School of Minerals, Energy and Chemical Engineering (MECE) will provide state-of-the-art