Cluster-mediated stop-and-go crystallization‬

A. E.S. Van Driessche; J. Lutsko; D. Maes; M. Sleutel

doi:10.1016/j.jcrysgro.2022.127024

Cluster-mediated stop-and-go crystallization‬

A. E.S. Van Driessche, J. Lutsko, D. Maes, M. Sleutel

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Abstract

Impurities control the formation of bio-crystals and can fully paralyze crystal growth at low levels of supersaturation. Traditional impurity models predict that an escape from this so-called “dead zone” requires an increase in the driving force (i.e. supersaturation). In this work, using protein crystals as a model system, we uncover an alternative escape route from the dead zone that does not involve an increase in supersaturation. We demonstrate that the merger of a protein cluster with the crystal surface triggers the formation of an ordered multi-layered island. The newly created surface on top of the resulting 3D island is initially devoid of impurities and therefore characterized by near-pure step growth kinetics. The accelerated step advancement on this relatively uncontaminated surface limits the available time for impurities to adsorb on the emerging terraces and by extension their resulting surface density. Cluster-mediated crystal growth occurring in heterogeneous media can therefore lead to stop-and-go dynamics, which offers a new model to explain crystallization taking place under biological control (e.g. biomineralization).

Original language	English
Article number	127024
Number of pages <span style="color:red"p> <font size="1.5"> ✽ </span> </font>	7
Journal	Journal of Crystal Growth
Volume	603
DOIs	https://doi.org/10.1016/j.jcrysgro.2022.127024
Publication status	Published - 1 Feb 2023

Bibliographical note

Funding Information:
This work was partially supported by the European Space Agency under Contract No. ESA AO-2004-070, FWO grant 1523115 N (Belgium) and scholarship BES·2003·2191 (AVD, Ministerio de Ciencia y Tecnologia, Spain).

Publisher Copyright:
© 2022 The Author(s)

Copyright:
Copyright 2023 Elsevier B.V., All rights reserved.

Keywords

A1 biocrystallization
A1 cluster-mediated growth
A1 dead zone
A1 impurities
A1 in situ observation step dynamics
A1 kinetic monte carlo

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Cite this

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title = "Cluster-mediated stop-and-go crystallization‬",

abstract = "Impurities control the formation of bio-crystals and can fully paralyze crystal growth at low levels of supersaturation. Traditional impurity models predict that an escape from this so-called “dead zone” requires an increase in the driving force (i.e. supersaturation). In this work, using protein crystals as a model system, we uncover an alternative escape route from the dead zone that does not involve an increase in supersaturation. We demonstrate that the merger of a protein cluster with the crystal surface triggers the formation of an ordered multi-layered island. The newly created surface on top of the resulting 3D island is initially devoid of impurities and therefore characterized by near-pure step growth kinetics. The accelerated step advancement on this relatively uncontaminated surface limits the available time for impurities to adsorb on the emerging terraces and by extension their resulting surface density. Cluster-mediated crystal growth occurring in heterogeneous media can therefore lead to stop-and-go dynamics, which offers a new model to explain crystallization taking place under biological control (e.g. biomineralization).",

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note = "Funding Information: This work was partially supported by the European Space Agency under Contract No. ESA AO-2004-070, FWO grant 1523115 N (Belgium) and scholarship BES·2003·2191 (AVD, Ministerio de Ciencia y Tecnologia, Spain). Publisher Copyright: {\textcopyright} 2022 The Author(s) Copyright: Copyright 2023 Elsevier B.V., All rights reserved.",

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N2 - Impurities control the formation of bio-crystals and can fully paralyze crystal growth at low levels of supersaturation. Traditional impurity models predict that an escape from this so-called “dead zone” requires an increase in the driving force (i.e. supersaturation). In this work, using protein crystals as a model system, we uncover an alternative escape route from the dead zone that does not involve an increase in supersaturation. We demonstrate that the merger of a protein cluster with the crystal surface triggers the formation of an ordered multi-layered island. The newly created surface on top of the resulting 3D island is initially devoid of impurities and therefore characterized by near-pure step growth kinetics. The accelerated step advancement on this relatively uncontaminated surface limits the available time for impurities to adsorb on the emerging terraces and by extension their resulting surface density. Cluster-mediated crystal growth occurring in heterogeneous media can therefore lead to stop-and-go dynamics, which offers a new model to explain crystallization taking place under biological control (e.g. biomineralization).

AB - Impurities control the formation of bio-crystals and can fully paralyze crystal growth at low levels of supersaturation. Traditional impurity models predict that an escape from this so-called “dead zone” requires an increase in the driving force (i.e. supersaturation). In this work, using protein crystals as a model system, we uncover an alternative escape route from the dead zone that does not involve an increase in supersaturation. We demonstrate that the merger of a protein cluster with the crystal surface triggers the formation of an ordered multi-layered island. The newly created surface on top of the resulting 3D island is initially devoid of impurities and therefore characterized by near-pure step growth kinetics. The accelerated step advancement on this relatively uncontaminated surface limits the available time for impurities to adsorb on the emerging terraces and by extension their resulting surface density. Cluster-mediated crystal growth occurring in heterogeneous media can therefore lead to stop-and-go dynamics, which offers a new model to explain crystallization taking place under biological control (e.g. biomineralization).

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Cluster-mediated stop-and-go crystallization‬

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Keywords

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