Synthesis, characterization, CO2 mineralization in air, and thermal decomposition of nano- C8H10MgO10·4H2O powder

Synthesis, characterization, CO2 mineralization in air, and thermal decomposition of nano- C8H10MgO10·4H2O powder

Effective solutions for efficient carbon dioxide (CO2) capture in air at room temperature are in high demand due to the major impacts CO2 has on global climatic changes. Solid adsorbents materials for CO2 capture received great attention over the past years, among them, magnesium-based sorbents have...

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Veröffentlicht in:Journal of environmental management 2021-10, Vol.295, p.113095-113095, Article 113095
Hauptverfasser: Senevirathna, Hasanthi L., Lebedev, Andrei, Chen, Victor Yaohui, Chou, Chuen-Shii, Wu, Ping
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Sprache:eng
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Aging
CO2 adsorption
Electrospinning
Magnesium carbonate hydrate
Mineralizing of CO2
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container_title Journal of environmental management
container_volume 295
creator Senevirathna, Hasanthi L.
Lebedev, Andrei
Chen, Victor Yaohui
Chou, Chuen-Shii
Wu, Ping
description Effective solutions for efficient carbon dioxide (CO2) capture in air at room temperature are in high demand due to the major impacts CO2 has on global climatic changes. Solid adsorbents materials for CO2 capture received great attention over the past years, among them, magnesium-based sorbents have been identified as a promising solution for CO2 capture at intermediate temperatures. This study reports for the first time (1) the synthesis of monoclinic magnesium malate tetrahydrate by combining electrospinning and aging processes, and (2) its room temperature CO2 adsorption and mineralization in air. Commercial magnesium hydroxide (Mg(OH)2) powder was used as raw material in the synthesis of magnesium carbonate hydrates (MCH), by three processes; (1) direct calcination, (2) electrospinning and calcination, and (3) electrospinning, calcination, and aging (at room temperature and in air to incubate CO2 mineralization). The synthesized powder samples were characterized thoroughly using XRD, SEM, EDS, and TGA analyses. Effects of calcination temperature/aging time on CO2 adsorption (at room temperature), crystallization, and mineralization of MCH were studied. Interestingly, the results showed that the 6-month aged samples (via the third synthesis process above), recorded a CO2 adsorption capacity of 15.5 wt% within 90 min at 30 °C. Subsequently, three novel mechanisms of thermal decomposition CO2 adsorption/mineralization were proposed, and a theoretical upper limit of carbon saving potentials was estimated, i.e., 8 mol CO2 per 1 mol MgO. This work provides a novel CO2 mineralization approach that results in (1) effective and practical solutions of carbon dioxide (CO2) emission management and which holds (2) great potential for novel carbon-based fuels development. [Display omitted] •The first report on the synthesis of C8H10MgO10·4H2O and MgCO3·3H2O from Mg(OH)2 via mineralizing CO2.•The first report on a mineralizing CO2 process by combining electrospinning and aging approaches.•The first study on the mechanism of thermal decomposition and CO2 mineralization of C8H10MgO10·4H2O.•The first report on the CO2 mineralization pathway on a MgO–CO2–H2O ternary phase diagram.
doi_str_mv 10.1016/j.jenvman.2021.113095
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Solid adsorbents materials for CO2 capture received great attention over the past years, among them, magnesium-based sorbents have been identified as a promising solution for CO2 capture at intermediate temperatures. This study reports for the first time (1) the synthesis of monoclinic magnesium malate tetrahydrate by combining electrospinning and aging processes, and (2) its room temperature CO2 adsorption and mineralization in air. Commercial magnesium hydroxide (Mg(OH)2) powder was used as raw material in the synthesis of magnesium carbonate hydrates (MCH), by three processes; (1) direct calcination, (2) electrospinning and calcination, and (3) electrospinning, calcination, and aging (at room temperature and in air to incubate CO2 mineralization). The synthesized powder samples were characterized thoroughly using XRD, SEM, EDS, and TGA analyses. Effects of calcination temperature/aging time on CO2 adsorption (at room temperature), crystallization, and mineralization of MCH were studied. Interestingly, the results showed that the 6-month aged samples (via the third synthesis process above), recorded a CO2 adsorption capacity of 15.5 wt% within 90 min at 30 °C. Subsequently, three novel mechanisms of thermal decomposition CO2 adsorption/mineralization were proposed, and a theoretical upper limit of carbon saving potentials was estimated, i.e., 8 mol CO2 per 1 mol MgO. This work provides a novel CO2 mineralization approach that results in (1) effective and practical solutions of carbon dioxide (CO2) emission management and which holds (2) great potential for novel carbon-based fuels development. 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Solid adsorbents materials for CO2 capture received great attention over the past years, among them, magnesium-based sorbents have been identified as a promising solution for CO2 capture at intermediate temperatures. This study reports for the first time (1) the synthesis of monoclinic magnesium malate tetrahydrate by combining electrospinning and aging processes, and (2) its room temperature CO2 adsorption and mineralization in air. Commercial magnesium hydroxide (Mg(OH)2) powder was used as raw material in the synthesis of magnesium carbonate hydrates (MCH), by three processes; (1) direct calcination, (2) electrospinning and calcination, and (3) electrospinning, calcination, and aging (at room temperature and in air to incubate CO2 mineralization). The synthesized powder samples were characterized thoroughly using XRD, SEM, EDS, and TGA analyses. Effects of calcination temperature/aging time on CO2 adsorption (at room temperature), crystallization, and mineralization of MCH were studied. Interestingly, the results showed that the 6-month aged samples (via the third synthesis process above), recorded a CO2 adsorption capacity of 15.5 wt% within 90 min at 30 °C. Subsequently, three novel mechanisms of thermal decomposition CO2 adsorption/mineralization were proposed, and a theoretical upper limit of carbon saving potentials was estimated, i.e., 8 mol CO2 per 1 mol MgO. This work provides a novel CO2 mineralization approach that results in (1) effective and practical solutions of carbon dioxide (CO2) emission management and which holds (2) great potential for novel carbon-based fuels development. 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Solid adsorbents materials for CO2 capture received great attention over the past years, among them, magnesium-based sorbents have been identified as a promising solution for CO2 capture at intermediate temperatures. This study reports for the first time (1) the synthesis of monoclinic magnesium malate tetrahydrate by combining electrospinning and aging processes, and (2) its room temperature CO2 adsorption and mineralization in air. Commercial magnesium hydroxide (Mg(OH)2) powder was used as raw material in the synthesis of magnesium carbonate hydrates (MCH), by three processes; (1) direct calcination, (2) electrospinning and calcination, and (3) electrospinning, calcination, and aging (at room temperature and in air to incubate CO2 mineralization). The synthesized powder samples were characterized thoroughly using XRD, SEM, EDS, and TGA analyses. Effects of calcination temperature/aging time on CO2 adsorption (at room temperature), crystallization, and mineralization of MCH were studied. Interestingly, the results showed that the 6-month aged samples (via the third synthesis process above), recorded a CO2 adsorption capacity of 15.5 wt% within 90 min at 30 °C. Subsequently, three novel mechanisms of thermal decomposition CO2 adsorption/mineralization were proposed, and a theoretical upper limit of carbon saving potentials was estimated, i.e., 8 mol CO2 per 1 mol MgO. This work provides a novel CO2 mineralization approach that results in (1) effective and practical solutions of carbon dioxide (CO2) emission management and which holds (2) great potential for novel carbon-based fuels development. 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subjects Aging
CO2 adsorption
Electrospinning
Magnesium carbonate hydrate
Mineralizing of CO2
title Synthesis, characterization, CO2 mineralization in air, and thermal decomposition of nano- C8H10MgO10·4H2O powder
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