ACEME: Direct Aqueous Mineral Carbonation of Dunite Rock

Rashid, Muhammad Imran; Benhelal, Emad; Farhang, Faezeh; Oliver, T.K.; Rayson, Mark S.; Brent, Geoff F.; Stockenhuber, Michael; Kennedy, Eric M.

doi:10.1002/ep.13075

Cited by 19 publications

(21 citation statements)

References 27 publications

(43 reference statements)

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“…A temperature of 650 • C is sufficient for lizardite to complete dehydroxylation [36]. In our previous publication, we established that heat-activated dunite provided higher magnesite yields compared to that of heat-transformed dunite (forsterite rich) and raw dunite [4]. The aim of this work was to confirm these magnesite yield results through a second approach, i.e., Mg extraction using acid dissolution experiments.…”

Section: Introductionmentioning

confidence: 66%

“…Warming of 2 • C would release billions of tons of soil carbon [2]. Geological storage, oceanic storage, and recently mineral carbonation, are among different candidates for CO 2 sequestration to prevent its emissions to the atmosphere [3,4]. Mineral carbonation, mainly using naturally abundant Mg-silicates, can offer safe storage of CO 2 in the form of mineral carbonates for many centuries [5,6].…”

Section: Introductionmentioning

confidence: 99%

“…Single stage [4,[6][7][8][9][10][11][12] and two-stage carbonation [13][14][15][16][17][18][19] are different processes that are being extensively studied for CO 2 capture, utilization, and storage. Initial studies on mineral carbonation showed relatively slow reaction kinetics [20].…”

Section: Introductionmentioning

confidence: 99%

“…Compared to other magnesium silicate minerals that have been studied for mineral carbonation, dunite is more complex as it is usually a mixture of minerals. One example that has previously been studied contains 61%-62% lizardite, 30%-33% olivine, 3.8%-8.3% brucite, and 0.6% magnetite [4]. Heat activation can be used to convert the lizardite present in dunite into more reactive amorphous Mg-silicate phases.…”

Section: Introductionmentioning

confidence: 99%

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Magnesium Leachability of Mg-Silicate Peridotites: The Effect on Magnesite Yield of a Mineral Carbonation Process

et al. 2020

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The aim of this study was to increase feedstock availability for mineral carbonation. Acid dissolution and carbonic acid dissolution approaches were used to achieve higher Mg extractions from peridotites. Acid dissolution studies of raw dunite, heat-activated dunite, heat-transformed dunite, and twin sister dunite have not been reported in the literature. Heat-activated dunite is more reactive as compared to heat-transformed dunite, raw dunite, and twin sister dunite. The fraction of magnesium extracted from heat-activated dunite was 57% as compared to 18% from heat-transformed dunite, 14% from raw dunite, and 11% from twin sister dunite. Similarly, silicon and iron extractions were higher for heat-activated dunite compared to that of heat-transformed dunite, raw dunite, and twin sister dunite. Materials rich in forsterite (twin sister dunite and heat-transformed dunite) showed preferential Mg release and exhibited incongruent dissolution similar to that of forsterite. Heat-activated dunite (amorphous magnesium silicate rich) on the other hand behaved differently and showed congruent dissolution. Olivine did not dissolve under carbonic acid dissolution (with concurrent grinding) and acidic conditions. Under carbonic acid dissolution with concurrent grinding conditions, olivine was partially converted into nanometer sized particles (d10 = 0.08 µm) but still provided 16% Mg extraction during 4 h of dissolution.

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Section: Introductionmentioning

confidence: 66%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Magnesium Leachability of Mg-Silicate Peridotites: The Effect on Magnesite Yield of a Mineral Carbonation Process

et al. 2020

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“…Their research and technical facilities are centred at the University of Newcastle, Australia. MCi's suite of projects includes fundamental theoretical and laboratory research [66,[95][96][97][98][99][100] as well as one of the world's first mineral carbonation pilot plant facilities [101,102]. MCi's project has primarily been studying the carbonation of serpentine, which as mentioned above is an abundant mineral in New South Wales (NSW), Australia and globally [102].…”

Section: Mineral Carbonation In Australiamentioning

confidence: 99%

Opportunities for Mineral Carbonation in Australia’s Mining Industry

et al. 2019

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Carbon capture, utilisation and storage (CCUS) via mineral carbonation is an effective method for long-term storage of carbon dioxide and combating climate change. Implemented at a large-scale, it provides a viable solution to harvesting and storing the modern crisis of GHGs emissions. To date, technological and economic barriers have inhibited broad-scale utilisation of mineral carbonation at industrial scales. This paper outlines the mineral carbonation process; discusses drivers and barriers of mineral carbonation deployment in Australian mining; and, finally, proposes a unique approach to commercially viable CCUS within the Australian mining industry by integrating mine waste management with mine site rehabilitation, and leveraging relationships with local coal-fired power station. This paper discusses using alkaline mine and coal-fired power station waste (fly ash, red mud, and ultramafic mine tailings, i.e., nickel, diamond, PGE (platinum group elements), and legacy asbestos mine tailings) as the feedstock for CCUS to produce environmentally benign materials, which can be used in mine reclamation. Geographical proximity of mining operations, mining waste storage facilities and coal-fired power stations in Australia are identified; and possible synergies between them are discussed. This paper demonstrates that large-scale alkaline waste production and mine site reclamation can become integrated to mechanise CCUS. Furthermore, financial liabilities associated with such waste management and site reclamation could overcome many of the current economic setbacks of retrofitting CCUS in the mining industry. An improved approach to commercially viable climate change mitigation strategies available to the mining industry is reviewed in this paper.

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Reduction of Greenhouse Gas Emissions from Gas, Oil, and Coal Power Plants in Pakistan by Carbon Capture and Storage (CCS): A Review

2020

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The production of energy in Pakistan as a developing country mainly depends on consumption of fossil fuels, which are the main sources of greenhouse gas (GHG) emissions. These emissions can be mitigated by implementing carbon capture and storage (CCS) in running plants. An overview of the current and future potentials of Pakistan for CCS is provided, indicating a great potential for this technology to capture CO 2 emissions. The amine CO 2 capture process as the most mature procedure is currently applied in many oil and gas companies in Pakistan, which can be employed to capture CO 2 from other industries as well. Pakistan has a great CO 2 storage potential in oil, gas, and coal fields and in saline aquifer as well as significant resources of Mg and Ca silicates suitable as feedstock in the carbon mineralization process. For further development and implementation of CCS technologies in Pakistan, economic and policy barriers as the main obstacles should be alleviated.

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ACEME: Direct Aqueous Mineral Carbonation of Dunite Rock

Cited by 19 publications

References 27 publications

Magnesium Leachability of Mg-Silicate Peridotites: The Effect on Magnesite Yield of a Mineral Carbonation Process

Magnesium Leachability of Mg-Silicate Peridotites: The Effect on Magnesite Yield of a Mineral Carbonation Process

Opportunities for Mineral Carbonation in Australia’s Mining Industry

Reduction of Greenhouse Gas Emissions from Gas, Oil, and Coal Power Plants in Pakistan by Carbon Capture and Storage (CCS): A Review

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