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Autores principales: Rechav, Zoë, Tambutté, Eric, LeCloux, Isabelle M, Anglemyer, Samantha, Beltz, Natalie E, Chou, Nicolas A, Dixson-Kruijf, Brynne E, Domagk, Johannes, Larson, Anders M, Lewis, Sylvia W, Rich, Rhita, Saheed, Lateef O, Schwenk, James L, Sengkhammee, Jaden S, Waltenberg, Christian A, Ye, Jianfeng, Achinuq, Barat Q, Venn, Alexander A, Tambutté, Sylvie, Gilbert, Pupa U P A
Formato: Artículo científico
Lenguaje:en
Publicado: Nature communications 2026
Materias:
Acceso en línea:https://pubmed.ncbi.nlm.nih.gov/41702911/
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author Rechav, Zoë
Tambutté, Eric
LeCloux, Isabelle M
Anglemyer, Samantha
Beltz, Natalie E
Chou, Nicolas A
Dixson-Kruijf, Brynne E
Domagk, Johannes
Larson, Anders M
Lewis, Sylvia W
Rich, Rhita
Saheed, Lateef O
Schwenk, James L
Sengkhammee, Jaden S
Waltenberg, Christian A
Ye, Jianfeng
Achinuq, Barat Q
Venn, Alexander A
Tambutté, Sylvie
Gilbert, Pupa U P A
author_facet Rechav, Zoë
Tambutté, Eric
LeCloux, Isabelle M
Anglemyer, Samantha
Beltz, Natalie E
Chou, Nicolas A
Dixson-Kruijf, Brynne E
Domagk, Johannes
Larson, Anders M
Lewis, Sylvia W
Rich, Rhita
Saheed, Lateef O
Schwenk, James L
Sengkhammee, Jaden S
Waltenberg, Christian A
Ye, Jianfeng
Achinuq, Barat Q
Venn, Alexander A
Tambutté, Sylvie
Gilbert, Pupa U P A
Rechav, Zoë
Tambutté, Eric
LeCloux, Isabelle M
Anglemyer, Samantha
Beltz, Natalie E
Chou, Nicolas A
Dixson-Kruijf, Brynne E
Domagk, Johannes
Larson, Anders M
Lewis, Sylvia W
Rich, Rhita
Saheed, Lateef O
Schwenk, James L
Sengkhammee, Jaden S
Waltenberg, Christian A
Ye, Jianfeng
Achinuq, Barat Q
Venn, Alexander A
Tambutté, Sylvie
Gilbert, Pupa U P A
collection PubMed - marine biology
contents Exponential crystallization in corals. Rechav, Zoë Tambutté, Eric LeCloux, Isabelle M Anglemyer, Samantha Beltz, Natalie E Chou, Nicolas A Dixson-Kruijf, Brynne E Domagk, Johannes Larson, Anders M Lewis, Sylvia W Rich, Rhita Saheed, Lateef O Schwenk, James L Sengkhammee, Jaden S Waltenberg, Christian A Ye, Jianfeng Achinuq, Barat Q Venn, Alexander A Tambutté, Sylvie Gilbert, Pupa U P A Animals Anthozoa Crystallization Calcium Carbonate Hydrogen-Ion Concentration Seawater Biomineralization Calcification, Physiologic Kinetics Corals form their reef-building aragonite (CaCO) skeletons via transient precursor phases yet understanding of the dynamics of these early-stage transformations remains incomplete. Using time-independent myriad mapping (MM) at 50 nm resolution, we map five mineral phases near the skeleton surface of Stylophora pistillata corals grown in varying seawater pH. All precursors, crystalline and amorphous, exhibit a consistent exponential decay from the growth front, with a shared decay length of 0.7 ± 0.1 μm, independent of time, phase, or pH. This spatial decay, paired with the constant growth rate of the skeleton, reveals a decay time of 5.1 ± 0.5 minutes. The dominant precursor is not amorphous but crystalline: calcium carbonate hemihydrate (CCHH, CaCO₃·½H₂O). These results suggest that exponential crystallization kinetics govern coral biomineralization and may be a widespread feature in biogenic, geologic, and synthetic systems-traceable long after initial mineral deposition.
format Artículo científico
id pubmed_41702911
institution PubMed
language en
publishDate 2026
publisher Nature communications
record_format pubmed
spellingShingle Exponential crystallization in corals.
Rechav, Zoë
Tambutté, Eric
LeCloux, Isabelle M
Anglemyer, Samantha
Beltz, Natalie E
Chou, Nicolas A
Dixson-Kruijf, Brynne E
Domagk, Johannes
Larson, Anders M
Lewis, Sylvia W
Rich, Rhita
Saheed, Lateef O
Schwenk, James L
Sengkhammee, Jaden S
Waltenberg, Christian A
Ye, Jianfeng
Achinuq, Barat Q
Venn, Alexander A
Tambutté, Sylvie
Gilbert, Pupa U P A
Animals
Anthozoa
Crystallization
Calcium Carbonate
Hydrogen-Ion Concentration
Seawater
Biomineralization
Calcification, Physiologic
Kinetics
Exponential crystallization in corals. Rechav, Zoë Tambutté, Eric LeCloux, Isabelle M Anglemyer, Samantha Beltz, Natalie E Chou, Nicolas A Dixson-Kruijf, Brynne E Domagk, Johannes Larson, Anders M Lewis, Sylvia W Rich, Rhita Saheed, Lateef O Schwenk, James L Sengkhammee, Jaden S Waltenberg, Christian A Ye, Jianfeng Achinuq, Barat Q Venn, Alexander A Tambutté, Sylvie Gilbert, Pupa U P A Animals Anthozoa Crystallization Calcium Carbonate Hydrogen-Ion Concentration Seawater Biomineralization Calcification, Physiologic Kinetics Corals form their reef-building aragonite (CaCO) skeletons via transient precursor phases yet understanding of the dynamics of these early-stage transformations remains incomplete. Using time-independent myriad mapping (MM) at 50 nm resolution, we map five mineral phases near the skeleton surface of Stylophora pistillata corals grown in varying seawater pH. All precursors, crystalline and amorphous, exhibit a consistent exponential decay from the growth front, with a shared decay length of 0.7 ± 0.1 μm, independent of time, phase, or pH. This spatial decay, paired with the constant growth rate of the skeleton, reveals a decay time of 5.1 ± 0.5 minutes. The dominant precursor is not amorphous but crystalline: calcium carbonate hemihydrate (CCHH, CaCO₃·½H₂O). These results suggest that exponential crystallization kinetics govern coral biomineralization and may be a widespread feature in biogenic, geologic, and synthetic systems-traceable long after initial mineral deposition.
title Exponential crystallization in corals.
topic Animals
Anthozoa
Crystallization
Calcium Carbonate
Hydrogen-Ion Concentration
Seawater
Biomineralization
Calcification, Physiologic
Kinetics
url https://pubmed.ncbi.nlm.nih.gov/41702911/