Dehydration-Driven Glass Formation in Aqueous Carbonates

Thilo Bissbort; Kai Uwe Hess; Daniel Weidendorfer; Elena V. Sturm; Jürgen E.K. Schawe; Martin Wilding; Bettina Purgstaller; Katja E. Goetschl; Sebastian Sturm; Knut Müller-Caspary; Wolfgang Schmahl; Erika Griesshaber; Martin Dietzel; Donald B. Dingwell

doi:10.1021/acs.jpclett.5c00551

Dehydration-Driven Glass Formation in Aqueous Carbonates

Thilo Bissbort^*, Kai Uwe Hess, Daniel Weidendorfer, Elena V. Sturm, Jürgen E.K. Schawe, Martin Wilding, Bettina Purgstaller, Katja E. Goetschl, Sebastian Sturm, Knut Müller-Caspary, Wolfgang Schmahl, Erika Griesshaber, Martin Dietzel, Donald B. Dingwell

^*Corresponding author for this work

Institute of Applied Geosciences (2210)

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

Abstract

Amorphous carbonates, in their liquid and solid (glassy) forms, have been identified to play important roles in biomineralization, volcanism, and deep element cycling. Anhydrous amorphous calcium and calcium-magnesium carbonate (ACC and ACMC05, respectively) are structural glasses that exhibit a glass transition upon being heated. We report a significant effect of the water content on glass formation. The results yield a parametrization enabling prediction of the stability of their liquid and solid amorphous phases as a function of temperature and water content. These results, obtained through novel fast differential scanning calorimetry, demonstrate that hydrous ACC and ACMC05 do indeed exhibit the behavior of structural glasses and that dehydration of these materials by lyophilization is a route that can be used to isothermally cross the glass transition. This work presents a viable process for a significantly wider range of geo- and biomaterials. Dehydration-controlled formation of glassy ACC therefore constitutes the missing link in the transformation from supersaturated aqueous solutions through an intermediate amorphous glassy state to crystalline CaCO₃ polymorphs. These results yield direct implications for the mechanistic interpretation of geological processes and biomineralization.

Original language	English
Pages (from-to)	4773-4779
Number of pages	7
Journal	Journal of Physical Chemistry Letters
Volume	16
Issue number	19
DOIs	https://doi.org/10.1021/acs.jpclett.5c00551
Publication status	Published - 15 May 2025

ASJC Scopus subject areas

General Materials Science
Physical and Theoretical Chemistry

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Bissbort, T., Hess, K. U., Weidendorfer, D., Sturm, E. V., Schawe, J. E. K., Wilding, M., Purgstaller, B., Goetschl, K. E., Sturm, S., Müller-Caspary, K., Schmahl, W., Griesshaber, E., Dietzel, M., & Dingwell, D. B. (2025). Dehydration-Driven Glass Formation in Aqueous Carbonates. Journal of Physical Chemistry Letters, 16(19), 4773-4779. https://doi.org/10.1021/acs.jpclett.5c00551

Bissbort, T, Hess, KU, Weidendorfer, D, Sturm, EV, Schawe, JEK, Wilding, M, Purgstaller, B, Goetschl, KE, Sturm, S, Müller-Caspary, K, Schmahl, W, Griesshaber, E, Dietzel, M & Dingwell, DB 2025, 'Dehydration-Driven Glass Formation in Aqueous Carbonates', Journal of Physical Chemistry Letters, vol. 16, no. 19, pp. 4773-4779. https://doi.org/10.1021/acs.jpclett.5c00551

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title = "Dehydration-Driven Glass Formation in Aqueous Carbonates",

abstract = "Amorphous carbonates, in their liquid and solid (glassy) forms, have been identified to play important roles in biomineralization, volcanism, and deep element cycling. Anhydrous amorphous calcium and calcium-magnesium carbonate (ACC and ACMC05, respectively) are structural glasses that exhibit a glass transition upon being heated. We report a significant effect of the water content on glass formation. The results yield a parametrization enabling prediction of the stability of their liquid and solid amorphous phases as a function of temperature and water content. These results, obtained through novel fast differential scanning calorimetry, demonstrate that hydrous ACC and ACMC05 do indeed exhibit the behavior of structural glasses and that dehydration of these materials by lyophilization is a route that can be used to isothermally cross the glass transition. This work presents a viable process for a significantly wider range of geo- and biomaterials. Dehydration-controlled formation of glassy ACC therefore constitutes the missing link in the transformation from supersaturated aqueous solutions through an intermediate amorphous glassy state to crystalline CaCO3 polymorphs. These results yield direct implications for the mechanistic interpretation of geological processes and biomineralization.",

author = "Thilo Bissbort and Hess, {Kai Uwe} and Daniel Weidendorfer and Sturm, {Elena V.} and Schawe, {J{\"u}rgen E.K.} and Martin Wilding and Bettina Purgstaller and Goetschl, {Katja E.} and Sebastian Sturm and Knut M{\"u}ller-Caspary and Wolfgang Schmahl and Erika Griesshaber and Martin Dietzel and Dingwell, {Donald B.}",

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doi = "10.1021/acs.jpclett.5c00551",

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AU - Bissbort, Thilo

AU - Hess, Kai Uwe

AU - Weidendorfer, Daniel

AU - Sturm, Elena V.

AU - Schawe, Jürgen E.K.

AU - Wilding, Martin

AU - Purgstaller, Bettina

AU - Goetschl, Katja E.

AU - Sturm, Sebastian

AU - Müller-Caspary, Knut

AU - Schmahl, Wolfgang

AU - Griesshaber, Erika

AU - Dietzel, Martin

AU - Dingwell, Donald B.

PY - 2025/5/15

Y1 - 2025/5/15

N2 - Amorphous carbonates, in their liquid and solid (glassy) forms, have been identified to play important roles in biomineralization, volcanism, and deep element cycling. Anhydrous amorphous calcium and calcium-magnesium carbonate (ACC and ACMC05, respectively) are structural glasses that exhibit a glass transition upon being heated. We report a significant effect of the water content on glass formation. The results yield a parametrization enabling prediction of the stability of their liquid and solid amorphous phases as a function of temperature and water content. These results, obtained through novel fast differential scanning calorimetry, demonstrate that hydrous ACC and ACMC05 do indeed exhibit the behavior of structural glasses and that dehydration of these materials by lyophilization is a route that can be used to isothermally cross the glass transition. This work presents a viable process for a significantly wider range of geo- and biomaterials. Dehydration-controlled formation of glassy ACC therefore constitutes the missing link in the transformation from supersaturated aqueous solutions through an intermediate amorphous glassy state to crystalline CaCO3 polymorphs. These results yield direct implications for the mechanistic interpretation of geological processes and biomineralization.

AB - Amorphous carbonates, in their liquid and solid (glassy) forms, have been identified to play important roles in biomineralization, volcanism, and deep element cycling. Anhydrous amorphous calcium and calcium-magnesium carbonate (ACC and ACMC05, respectively) are structural glasses that exhibit a glass transition upon being heated. We report a significant effect of the water content on glass formation. The results yield a parametrization enabling prediction of the stability of their liquid and solid amorphous phases as a function of temperature and water content. These results, obtained through novel fast differential scanning calorimetry, demonstrate that hydrous ACC and ACMC05 do indeed exhibit the behavior of structural glasses and that dehydration of these materials by lyophilization is a route that can be used to isothermally cross the glass transition. This work presents a viable process for a significantly wider range of geo- and biomaterials. Dehydration-controlled formation of glassy ACC therefore constitutes the missing link in the transformation from supersaturated aqueous solutions through an intermediate amorphous glassy state to crystalline CaCO3 polymorphs. These results yield direct implications for the mechanistic interpretation of geological processes and biomineralization.

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Dehydration-Driven Glass Formation in Aqueous Carbonates

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