Influencing Factors of the Mineral Carbonation Process of Iron Ore Mining Waste in Sequestering Atmospheric Carbon Dioxide

Influencing Factors of the Mineral Carbonation Process of Iron Ore Mining Waste in Sequestering Atmospheric Carbon Dioxide

Mining waste may contain potential minerals that can act as essential feedstock for long-term carbon sequestration through a mineral carbonation process. This study attempts to identify the mineralogical and chemical composition of iron ore mining waste alongside the effects of particle size, temper...

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Main Authors: Noor Allesya Alis Ramli, Faradiella Mohd Kusin, Verma Loretta M. Molahid
Format: Article
Language:English
Published: MDPI AG 2021-02-01
Series:Sustainability
Subjects:
carbon sequestration
carbon storage
iron ore
mineral carbonation
mining waste
sustainable production
Online Access:https://www.mdpi.com/2071-1050/13/4/1866
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spelling doaj-0d486491689e4469a42c1566c64e7a4b2021-02-10T00:01:26ZengMDPI AGSustainability2071-10502021-02-01131866186610.3390/su13041866Influencing Factors of the Mineral Carbonation Process of Iron Ore Mining Waste in Sequestering Atmospheric Carbon DioxideNoor Allesya Alis Ramli0Faradiella Mohd Kusin1Verma Loretta M. Molahid2Department of Environment, Faculty of Forestry and Environment, University Putra Malaysia, Serdang 43400, MalaysiaDepartment of Environment, Faculty of Forestry and Environment, University Putra Malaysia, Serdang 43400, MalaysiaDepartment of Environment, Faculty of Forestry and Environment, University Putra Malaysia, Serdang 43400, MalaysiaMining waste may contain potential minerals that can act as essential feedstock for long-term carbon sequestration through a mineral carbonation process. This study attempts to identify the mineralogical and chemical composition of iron ore mining waste alongside the effects of particle size, temperature, and pH on carbonation efficiency. The samples were found to be alkaline in nature (pH of 6.9–7.5) and contained small-sized particles of clay and silt, thus indicating their suitability for mineral carbonation reactions. Samples were composed of important silicate minerals needed for the formation of carbonates such as wollastonite, anorthite, diopside, perovskite, johannsenite, and magnesium aluminum silicate, and the Fe-bearing mineral magnetite. The presence of Fe<sub>2</sub>O<sub>3</sub> (39.6–62.9%) and CaO (7.2–15.2%) indicated the potential of the waste to sequester carbon dioxide because these oxides are important divalent cations for mineral carbonation. The use of small-sized mine-waste particles enables the enhancement of carbonation efficiency, i.e., particles of <38 µm showed a greater extent of Fe and Ca carbonation efficiency (between 1.6–6.7%) compared to particles of <63 µm (0.9–5.7%) and 75 µm (0.7–6.0%). Increasing the reaction temperature from 80 °C to 150–200 °C resulted in a higher Fe and Ca carbonation efficiency of some samples between 0.9–5.8% and 0.8–4.0%, respectively. The effect of increasing the pH from 8–12 was notably observed in Fe carbonation efficiency of between 0.7–5.9% (pH 12) compared to 0.6–3.3% (pH 8). Ca carbonation efficiency was moderately observed (0.7–5.5%) as with the increasing pH between 8–10. Therefore, it has been evidenced that mineralogical and chemical composition were of great importance for the mineral carbonation process, and that the effects of particle size, pH, and temperature of iron mining waste were influential in determining carbonation efficiency. Findings would be beneficial for sustaining the mining industry while taking into account the issue of waste production in tackling the global carbon emission concerns.https://www.mdpi.com/2071-1050/13/4/1866carbon sequestrationcarbon storageiron oremineral carbonationmining wastesustainable production
collection DOAJ
language English
format Article
sources DOAJ
author Noor Allesya Alis Ramli
Faradiella Mohd Kusin
Verma Loretta M. Molahid
spellingShingle Noor Allesya Alis Ramli
Faradiella Mohd Kusin
Verma Loretta M. Molahid
Influencing Factors of the Mineral Carbonation Process of Iron Ore Mining Waste in Sequestering Atmospheric Carbon Dioxide
Sustainability
carbon sequestration
carbon storage
iron ore
mineral carbonation
mining waste
sustainable production
author_facet Noor Allesya Alis Ramli
Faradiella Mohd Kusin
Verma Loretta M. Molahid
author_sort Noor Allesya Alis Ramli
title Influencing Factors of the Mineral Carbonation Process of Iron Ore Mining Waste in Sequestering Atmospheric Carbon Dioxide
title_short Influencing Factors of the Mineral Carbonation Process of Iron Ore Mining Waste in Sequestering Atmospheric Carbon Dioxide
title_full Influencing Factors of the Mineral Carbonation Process of Iron Ore Mining Waste in Sequestering Atmospheric Carbon Dioxide
title_fullStr Influencing Factors of the Mineral Carbonation Process of Iron Ore Mining Waste in Sequestering Atmospheric Carbon Dioxide
title_full_unstemmed Influencing Factors of the Mineral Carbonation Process of Iron Ore Mining Waste in Sequestering Atmospheric Carbon Dioxide
title_sort influencing factors of the mineral carbonation process of iron ore mining waste in sequestering atmospheric carbon dioxide
publisher MDPI AG
series Sustainability
issn 2071-1050
publishDate 2021-02-01
description Mining waste may contain potential minerals that can act as essential feedstock for long-term carbon sequestration through a mineral carbonation process. This study attempts to identify the mineralogical and chemical composition of iron ore mining waste alongside the effects of particle size, temperature, and pH on carbonation efficiency. The samples were found to be alkaline in nature (pH of 6.9–7.5) and contained small-sized particles of clay and silt, thus indicating their suitability for mineral carbonation reactions. Samples were composed of important silicate minerals needed for the formation of carbonates such as wollastonite, anorthite, diopside, perovskite, johannsenite, and magnesium aluminum silicate, and the Fe-bearing mineral magnetite. The presence of Fe<sub>2</sub>O<sub>3</sub> (39.6–62.9%) and CaO (7.2–15.2%) indicated the potential of the waste to sequester carbon dioxide because these oxides are important divalent cations for mineral carbonation. The use of small-sized mine-waste particles enables the enhancement of carbonation efficiency, i.e., particles of <38 µm showed a greater extent of Fe and Ca carbonation efficiency (between 1.6–6.7%) compared to particles of <63 µm (0.9–5.7%) and 75 µm (0.7–6.0%). Increasing the reaction temperature from 80 °C to 150–200 °C resulted in a higher Fe and Ca carbonation efficiency of some samples between 0.9–5.8% and 0.8–4.0%, respectively. The effect of increasing the pH from 8–12 was notably observed in Fe carbonation efficiency of between 0.7–5.9% (pH 12) compared to 0.6–3.3% (pH 8). Ca carbonation efficiency was moderately observed (0.7–5.5%) as with the increasing pH between 8–10. Therefore, it has been evidenced that mineralogical and chemical composition were of great importance for the mineral carbonation process, and that the effects of particle size, pH, and temperature of iron mining waste were influential in determining carbonation efficiency. Findings would be beneficial for sustaining the mining industry while taking into account the issue of waste production in tackling the global carbon emission concerns.
topic carbon sequestration
carbon storage
iron ore
mineral carbonation
mining waste
sustainable production
url https://www.mdpi.com/2071-1050/13/4/1866
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