Recovery of ultra-high purity reactive magnesia from reject brine and its comparison with commercial magnesia
CO2 emissions and energy consumption associated with ordinary Portland cement production have increased the urgency for the development of alternative construction materials. Reactive magnesia cement (RMC) has been widely studied in the recent years due to the lower calcination temperature used duri...
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sg-ntu-dr.10356-1740532024-03-15T15:33:18Z Recovery of ultra-high purity reactive magnesia from reject brine and its comparison with commercial magnesia Dong, Haoliang Xiao, Xi Yang, En-Hua Unluer, Cise School of Civil and Environmental Engineering Engineering Reject brine Oxalic acid CO2 emissions and energy consumption associated with ordinary Portland cement production have increased the urgency for the development of alternative construction materials. Reactive magnesia cement (RMC) has been widely studied in the recent years due to the lower calcination temperature used during its production and its ability to permanently sequester CO2. In addition to the calcination of magnesite, reactive MgO, the main component of RMC, can also be synthesized from reject brine, which is rich in Mg2+. However, the presence of other components such as calcium in reject brine leads to the precipitation of other mineral phases together with Mg(OH)2, thereby reducing the purity of the final product. With the goal of improving the purity and yield of MgO synthesized at the end of this process, this study proposed a selective precipitation approach under a controlled pH. An optimum condition was determined for the synthesis of magnesium oxalate dihydrate with an ultra-high purity of 99.6 % and a high magnesium recovery rate of 94.1 %. Reactive MgO with a specific surface area of 30.2 m2/g was obtained after the calcination of the synthesized magnesium oxalate dihydrate at 700 °C for 2 h, which was higher than some of the commercially available MgO powders. Ministry of National Development (MND) Published version This study was conducted via financial support from the Ministry of National Development, Singapore (CoT-V1-2020-1). Cise Unluer received financial support from The Royal Society (project ref.: ICA\R1 \201310). 2024-03-13T02:57:35Z 2024-03-13T02:57:35Z 2023 Journal Article Dong, H., Xiao, X., Yang, E. & Unluer, C. (2023). Recovery of ultra-high purity reactive magnesia from reject brine and its comparison with commercial magnesia. Desalination, 566, 116909-. https://dx.doi.org/10.1016/j.desal.2023.116909 0011-9164 https://hdl.handle.net/10356/174053 10.1016/j.desal.2023.116909 2-s2.0-85167570785 566 116909 en CoT-V1-2020-1 Desalination © 2023 The Authors. Published by Elsevier B.V. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/). application/pdf |
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Engineering Reject brine Oxalic acid |
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Engineering Reject brine Oxalic acid Dong, Haoliang Xiao, Xi Yang, En-Hua Unluer, Cise Recovery of ultra-high purity reactive magnesia from reject brine and its comparison with commercial magnesia |
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CO2 emissions and energy consumption associated with ordinary Portland cement production have increased the urgency for the development of alternative construction materials. Reactive magnesia cement (RMC) has been widely studied in the recent years due to the lower calcination temperature used during its production and its ability to permanently sequester CO2. In addition to the calcination of magnesite, reactive MgO, the main component of RMC, can also be synthesized from reject brine, which is rich in Mg2+. However, the presence of other components such as calcium in reject brine leads to the precipitation of other mineral phases together with Mg(OH)2, thereby reducing the purity of the final product. With the goal of improving the purity and yield of MgO synthesized at the end of this process, this study proposed a selective precipitation approach under a controlled pH. An optimum condition was determined for the synthesis of magnesium oxalate dihydrate with an ultra-high purity of 99.6 % and a high magnesium recovery rate of 94.1 %. Reactive MgO with a specific surface area of 30.2 m2/g was obtained after the calcination of the synthesized magnesium oxalate dihydrate at 700 °C for 2 h, which was higher than some of the commercially available MgO powders. |
| author2 |
School of Civil and Environmental Engineering |
| author_facet |
School of Civil and Environmental Engineering Dong, Haoliang Xiao, Xi Yang, En-Hua Unluer, Cise |
| format |
Article |
| author |
Dong, Haoliang Xiao, Xi Yang, En-Hua Unluer, Cise |
| author_sort |
Dong, Haoliang |
| title |
Recovery of ultra-high purity reactive magnesia from reject brine and its comparison with commercial magnesia |
| title_short |
Recovery of ultra-high purity reactive magnesia from reject brine and its comparison with commercial magnesia |
| title_full |
Recovery of ultra-high purity reactive magnesia from reject brine and its comparison with commercial magnesia |
| title_fullStr |
Recovery of ultra-high purity reactive magnesia from reject brine and its comparison with commercial magnesia |
| title_full_unstemmed |
Recovery of ultra-high purity reactive magnesia from reject brine and its comparison with commercial magnesia |
| title_sort |
recovery of ultra-high purity reactive magnesia from reject brine and its comparison with commercial magnesia |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/174053 |
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1794549296981344256 |