The development of novel geopolymers incorporating calcium and cellulosic material. Geopolymer technology transforms waste aluminosilicate materials into commercially viable products, which possess superior physical and chemical properties compared to ordinary concrete. These high-tech materials have novel acid and fire resistance applications, e.g. in construction and for the coating of optical fibres. Understanding the chemical relationship between geopolymers and other cementitious materials ....The development of novel geopolymers incorporating calcium and cellulosic material. Geopolymer technology transforms waste aluminosilicate materials into commercially viable products, which possess superior physical and chemical properties compared to ordinary concrete. These high-tech materials have novel acid and fire resistance applications, e.g. in construction and for the coating of optical fibres. Understanding the chemical relationship between geopolymers and other cementitious materials is pivotal to further advances in inorganic polymers. This project uses surface reactivity, spectroscopy, electronmicroscopy and electron diffraction to determine the role of calcium and cellulosic additives in the phase composition, microstructure and properties of geopolymers. Therefore, the factors distinguishing geopolymers from alkali-activated cement and ordinary concrete are identified.Read moreRead less
A fundamental study of the simultaneous gold dissolution during the alkaline oxidation of sulfide containing refractory gold ores and concentrates. The gold industry is Australia's second largest export earner and therefore is immensely important to the Australian economy. The proposed project aims to develop an environmentally acceptable process for treating gold containing sulfidic ores and concentrates that are not amenable to conventional cyanidation. This would provide an enormous benefit t ....A fundamental study of the simultaneous gold dissolution during the alkaline oxidation of sulfide containing refractory gold ores and concentrates. The gold industry is Australia's second largest export earner and therefore is immensely important to the Australian economy. The proposed project aims to develop an environmentally acceptable process for treating gold containing sulfidic ores and concentrates that are not amenable to conventional cyanidation. This would provide an enormous benefit to both the Australian gold industry and the Australian environment. A successful outcome in the research project would also lead to export earnings emanating from technology transfer and enhance Australia's reputation for high quality research and academic endeavours.Read moreRead less
Special Research Initiatives - Grant ID: SR0354672
Funder
Australian Research Council
Funding Amount
$20,000.00
Summary
ARC Network in Mineral Processing, Extraction and Refining. The Network aims to develop long-term, collaborative research and training links between world-class researchers and research centres in mineral processing, extraction and refining. The goal is to ensure that Australia's major export industry is sustainable, environmentally acceptable and technically at the cutting edge.
Networking key researchers with complementary skills and expertise will enhance research quality, encourage a hol ....ARC Network in Mineral Processing, Extraction and Refining. The Network aims to develop long-term, collaborative research and training links between world-class researchers and research centres in mineral processing, extraction and refining. The goal is to ensure that Australia's major export industry is sustainable, environmentally acceptable and technically at the cutting edge.
Networking key researchers with complementary skills and expertise will enhance research quality, encourage a holistic approach to problem solving and support researchers to tackle big challenges, beyond their usual scope, that will transform the industry. The outcomes will be greater international competitiveness, better resource utilisation, and the incubation of new research leaders, enhancing Australia's minerals R&D infrastructure.Read moreRead less
Australian Mineral Science Research Institute: Transformation of resource-based industries through the generation and application of new technologies. The research conducted within AMSRI will enable our existing resource-based industries to be transformed through the application of new technologies, helping to create an environmentally sustainable nation, a key national research priority. The research programs in energy efficient liberation, frugal water use and waste management, innovative proc ....Australian Mineral Science Research Institute: Transformation of resource-based industries through the generation and application of new technologies. The research conducted within AMSRI will enable our existing resource-based industries to be transformed through the application of new technologies, helping to create an environmentally sustainable nation, a key national research priority. The research programs in energy efficient liberation, frugal water use and waste management, innovative processing, material and interface science, advanced analysis and mathematics in minerals processing are of critical importance to Australia's major export industry. AMSRI will produce unique graduate students, educated in a multi-university, industry-linked research environment, who will provide a strong intellectual resource to both Australian industry and research institutions.Read moreRead less
BIOPROSPECTING FOR NOVEL EXTRACTANTS TO SEPARATE NICKEL AND COBALT. Cobalt (Co) is a common 'guest' element in nickel (Ni) ore. Separating these metals is crucial to the production of high purity of Ni and Co, valuable metals for the Australian economy. Currently, processing of Ni-ore relies on energy-intensive dissolution followed by separation of Co from Ni using expensive synthetic chelators. A few rare Ni- and Co-accumulating plants however, have evolved biochemical mechanisms to distingu ....BIOPROSPECTING FOR NOVEL EXTRACTANTS TO SEPARATE NICKEL AND COBALT. Cobalt (Co) is a common 'guest' element in nickel (Ni) ore. Separating these metals is crucial to the production of high purity of Ni and Co, valuable metals for the Australian economy. Currently, processing of Ni-ore relies on energy-intensive dissolution followed by separation of Co from Ni using expensive synthetic chelators. A few rare Ni- and Co-accumulating plants however, have evolved biochemical mechanisms to distinguish between Ni and Co. We propose the first determination of the mechanisms of Ni/Co discrimination in these unusual plants, effectively biosprospecting for novel commercial extractants to separate Ni and Co. Read moreRead less