Influence of additives, temperature, and pressure on the morphology of nesquehonite– results from three synthesis routes

Jens Back; Arnold Ismailov; Harisankar Srneenivasan; Jan-Henrik Smått; Hellen Silva Santos; Hoang Nguyen; Erkki Levanen; Ron Zevenhoven; Päivö  Kinnunen

doi:10.1007/s42247-024-00968-8

Influence of additives, temperature, and pressure on the morphology of nesquehonite– results from three synthesis routes

Jens Back
, Arnold Ismailov
, Harisankar Srneenivasan
, Jan-Henrik Smått
, Hellen Silva Santos^*
, Hoang Nguyen
, Erkki Levanen
, Ron Zevenhoven
, Päivö Kinnunen

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

1 Citation (Scopus)

30 Downloads (Pure)

Abstract

Carbon mineralization is expected to play a key role in the mitigation of climate change, as viable and efficient carbon capture and utilization (CCU) pathway. Indeed, the process has the advantage of enabling the recycling of waste-streams such as mine tailings or desalination brine, as well as the prospect of large-scale uptake of carbon dioxide emissions. However, the applications of the produced carbonates still hinder the commercial feasibility of the existing CCU routes, especially when hydrated Mg carbonates (HMCs) are obtained. HMCs are thermodynamically unstable, which poses potential risks in long-term stability. Nesquehonite (NQ, MgCO ₃·3H ₂O) is the major product of Mg carbonation in most aqueous reaction settings at moderate temperatures (15–50 °C), which has demonstrated suitable properties for producing construction materials. At somewhat higher temperatures (50–100 °C) hydromagnesite is obtained (4MgCO ₃·Mg(OH) ₂·4H ₂O). Yet, the final applications are not feasible as NQ often converts to hydromagnesite or other HMCs over time causing liberation of CO ₂ and volume instability. A key scientific gap remains on the relationship between the morphology of NQ with the operational settings of the carbonation reaction. In turn, such understanding is needed to enable tuning NQ applications in construction materials. Therefore, the current work reports the observed features of NQ via three different synthetic routes, showing the effect of two additives (Mg acetate, and sodium dodecyl sulphate), and overpressure CO ₂ on the physico-chemical features of NQ formed from magnesium chloride or sulphate solutions and from brucite-water system and sCO ₂ conditions.

Original language	English
Article number	https://doi.org/10.1007/s42247-024-00968-8
Pages (from-to)	2853-2868
Number of pages	16
Journal	Emergent Materials
Volume	8
Issue number	4
Early online date	7 Jan 2025
DOIs	https://doi.org/10.1007/s42247-024-00968-8
Publication status	Published - Apr 2025
MoE publication type	A1 Journal article-refereed

Funding

Open Access funding provided by University of Oulu (including Oulu University Hospital). H.S. and P.K. gratefully acknowledge the financial support received from Academy of Finland (grants 329477 and 326291). The authors would also like to thank Marcin Selent for his help with XRD measurement and Jani Österlund for the help with fiber measurement. Part of the work was carried out with the support of the Centre for Material Analysis, University of Oulu, Finland. This work has been carried out as a cross-collaboration work among the consortium partners of the MAGNEX project (Research council of Finland, funding decision 347185), being the funding agency acknowledged by H.N., H.S.S., A.I, E.L., J.B., R.Z. and P.K. At Åbo Akademi University, Jan-Henrik Smått is acknowledged for help with XRD analysis and Linus Silvander for SEM-EDS measurements.

Keywords

Carbon capture and utilization
Nesquehonite
Hydrated Mg carbonates
Supercritical CO2

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Cite this

Back, J., Ismailov, A., Srneenivasan, H., Smått, J.-H., Silva Santos, H., Nguyen, H., Levanen, E., Zevenhoven, R., & Kinnunen, P. (2025). Influence of additives, temperature, and pressure on the morphology of nesquehonite– results from three synthesis routes. Emergent Materials, 8(4), 2853-2868. Article https://doi.org/10.1007/s42247-024-00968-8. https://doi.org/10.1007/s42247-024-00968-8

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abstract = "Carbon mineralization is expected to play a key role in the mitigation of climate change, as viable and efficient carbon capture and utilization (CCU) pathway. Indeed, the process has the advantage of enabling the recycling of waste-streams such as mine tailings or desalination brine, as well as the prospect of large-scale uptake of carbon dioxide emissions. However, the applications of the produced carbonates still hinder the commercial feasibility of the existing CCU routes, especially when hydrated Mg carbonates (HMCs) are obtained. HMCs are thermodynamically unstable, which poses potential risks in long-term stability. Nesquehonite (NQ, MgCO 3·3H 2O) is the major product of Mg carbonation in most aqueous reaction settings at moderate temperatures (15–50 °C), which has demonstrated suitable properties for producing construction materials. At somewhat higher temperatures (50–100 °C) hydromagnesite is obtained (4MgCO 3·Mg(OH) 2·4H 2O). Yet, the final applications are not feasible as NQ often converts to hydromagnesite or other HMCs over time causing liberation of CO 2 and volume instability. A key scientific gap remains on the relationship between the morphology of NQ with the operational settings of the carbonation reaction. In turn, such understanding is needed to enable tuning NQ applications in construction materials. Therefore, the current work reports the observed features of NQ via three different synthetic routes, showing the effect of two additives (Mg acetate, and sodium dodecyl sulphate), and overpressure CO 2 on the physico-chemical features of NQ formed from magnesium chloride or sulphate solutions and from brucite-water system and sCO 2 conditions.",

keywords = "Carbon capture and utilization, Nesquehonite, Hydrated Mg carbonates, Supercritical CO2",

author = "Jens Back and Arnold Ismailov and Harisankar Srneenivasan and Jan-Henrik Sm{\aa}tt and \{Silva Santos\}, Hellen and Hoang Nguyen and Erkki Levanen and Ron Zevenhoven and P{\"a}iv{\"o} Kinnunen",

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Back, J, Ismailov, A, Srneenivasan, H, Smått, J-H, Silva Santos, H, Nguyen, H, Levanen, E, Zevenhoven, R & Kinnunen, P 2025, 'Influence of additives, temperature, and pressure on the morphology of nesquehonite– results from three synthesis routes', Emergent Materials, vol. 8, no. 4, https://doi.org/10.1007/s42247-024-00968-8, pp. 2853-2868. https://doi.org/10.1007/s42247-024-00968-8

Influence of additives, temperature, and pressure on the morphology of nesquehonite– results from three synthesis routes. / Back, Jens; Ismailov, Arnold; Srneenivasan, Harisankar et al.
In: Emergent Materials, Vol. 8, No. 4, https://doi.org/10.1007/s42247-024-00968-8, 04.2025, p. 2853-2868.

Research output: Contribution to journal › Article › Scientific › peer-review

TY - JOUR

T1 - Influence of additives, temperature, and pressure on the morphology of nesquehonite– results from three synthesis routes

AU - Back, Jens

AU - Ismailov, Arnold

AU - Srneenivasan, Harisankar

AU - Smått, Jan-Henrik

AU - Silva Santos, Hellen

AU - Nguyen, Hoang

AU - Levanen, Erkki

AU - Zevenhoven, Ron

AU - Kinnunen, Päivö

PY - 2025/4

Y1 - 2025/4

N2 - Carbon mineralization is expected to play a key role in the mitigation of climate change, as viable and efficient carbon capture and utilization (CCU) pathway. Indeed, the process has the advantage of enabling the recycling of waste-streams such as mine tailings or desalination brine, as well as the prospect of large-scale uptake of carbon dioxide emissions. However, the applications of the produced carbonates still hinder the commercial feasibility of the existing CCU routes, especially when hydrated Mg carbonates (HMCs) are obtained. HMCs are thermodynamically unstable, which poses potential risks in long-term stability. Nesquehonite (NQ, MgCO 3·3H 2O) is the major product of Mg carbonation in most aqueous reaction settings at moderate temperatures (15–50 °C), which has demonstrated suitable properties for producing construction materials. At somewhat higher temperatures (50–100 °C) hydromagnesite is obtained (4MgCO 3·Mg(OH) 2·4H 2O). Yet, the final applications are not feasible as NQ often converts to hydromagnesite or other HMCs over time causing liberation of CO 2 and volume instability. A key scientific gap remains on the relationship between the morphology of NQ with the operational settings of the carbonation reaction. In turn, such understanding is needed to enable tuning NQ applications in construction materials. Therefore, the current work reports the observed features of NQ via three different synthetic routes, showing the effect of two additives (Mg acetate, and sodium dodecyl sulphate), and overpressure CO 2 on the physico-chemical features of NQ formed from magnesium chloride or sulphate solutions and from brucite-water system and sCO 2 conditions.

AB - Carbon mineralization is expected to play a key role in the mitigation of climate change, as viable and efficient carbon capture and utilization (CCU) pathway. Indeed, the process has the advantage of enabling the recycling of waste-streams such as mine tailings or desalination brine, as well as the prospect of large-scale uptake of carbon dioxide emissions. However, the applications of the produced carbonates still hinder the commercial feasibility of the existing CCU routes, especially when hydrated Mg carbonates (HMCs) are obtained. HMCs are thermodynamically unstable, which poses potential risks in long-term stability. Nesquehonite (NQ, MgCO 3·3H 2O) is the major product of Mg carbonation in most aqueous reaction settings at moderate temperatures (15–50 °C), which has demonstrated suitable properties for producing construction materials. At somewhat higher temperatures (50–100 °C) hydromagnesite is obtained (4MgCO 3·Mg(OH) 2·4H 2O). Yet, the final applications are not feasible as NQ often converts to hydromagnesite or other HMCs over time causing liberation of CO 2 and volume instability. A key scientific gap remains on the relationship between the morphology of NQ with the operational settings of the carbonation reaction. In turn, such understanding is needed to enable tuning NQ applications in construction materials. Therefore, the current work reports the observed features of NQ via three different synthetic routes, showing the effect of two additives (Mg acetate, and sodium dodecyl sulphate), and overpressure CO 2 on the physico-chemical features of NQ formed from magnesium chloride or sulphate solutions and from brucite-water system and sCO 2 conditions.

KW - Carbon capture and utilization

KW - Nesquehonite

KW - Hydrated Mg carbonates

KW - Supercritical CO2

U2 - 10.1007/s42247-024-00968-8

DO - 10.1007/s42247-024-00968-8

M3 - Article

SN - 2522-5731

VL - 8

SP - 2853

EP - 2868

JO - Emergent Materials

JF - Emergent Materials

IS - 4

M1 - https://doi.org/10.1007/s42247-024-00968-8

ER -

Influence of additives, temperature, and pressure on the morphology of nesquehonite– results from three synthesis routes

Abstract

Funding

Keywords

UN SDGs

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