Concurrent Formation of Ice Network within Mineral Colloids with Suppressed Volume Expansion

Hongkun Li; Yunchen Long; Junda Shen; Xinxue Tang; Jiahua Liu; Chong Wang; Binbin Zhou; Bo Li; Jing Zhong; Xiao Ma; Chunyi Zhi; Jian Lu; Yang Yang Li

doi:10.1021/acs.jpclett.5c03627

Concurrent Formation of Ice Network within Mineral Colloids with Suppressed Volume Expansion

Hongkun Li, Yunchen Long, Junda Shen, Xinxue Tang, Jiahua Liu, Chong Wang, Binbin Zhou, Bo Li, Jing Zhong, Xiao Ma, Chunyi Zhi^*, Jian Lu^*, Yang Yang Li^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

Abstract

The freezing behaviors of water are one of the most critical factors that define the formats of life and the landscapes on Earth. The current methods for regulating the freezing behaviors mainly rely on ice-structuring proteins or nanomaterials to hinder the conversion of water into crystalline ice (I_h) under low temperatures. Here we report that the presence of minuscule mineral particles can significantly suppress the volume expansion of water upon freezing into ice. In particular, colloidal precipitates of calcite, a primary mineral accounting for ∼4 wt % of the Earth's crust and the most abundant biomineral on Earth, are able to reduce water expansion by 69% (from 8.4% to 2.6%) at 243 K. The mechanism of expansion suppression involves the formation of a continuous network of fairly ordered "ice-like" hydration waters that are bound to the surface of the mineral colloids at room temperature, and their concurrent crystallization through heterogeneous nucleation upon freezing, which confines the interstitial free water and refrains its volume expansion. These findings reveal the remarkable ability of common minerals to suppress a most ubiquitous phenomenon, water volume expansion upon freezing, and offer fresh insights into various fields such as biomineralization, hydrology, soil science, and lithology. © 2026 The Authors. Published by American Chemical Society.

Original language	English
Pages (from-to)	991-999
Number of pages	9
Journal	The Journal of Physical Chemistry Letters
Volume	17
Issue number	4
Online published	19 Jan 2026
DOIs	https://doi.org/10.1021/acs.jpclett.5c03627
Publication status	Published - 29 Jan 2026

Funding

This work was jointly supported by Hong Kong JLFS-RGCJoint Laboratory Funding Scheme (Grant No. JLFS/E-102/ 24), Guangdong Province Science and Technology Plan Project 2023B1212120008, Shenzhen Science and Technology Project (Project No: ZDSYS201602291653165), Hong Kong Innovation and Technology Commission via the Hong Kong Branch of National Precious Metals Material Engineering Research Center.

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This full text is made available under CC-BY 4.0. https://creativecommons.org/licenses/by/4.0/

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title = "Concurrent Formation of Ice Network within Mineral Colloids with Suppressed Volume Expansion",

abstract = "The freezing behaviors of water are one of the most critical factors that define the formats of life and the landscapes on Earth. The current methods for regulating the freezing behaviors mainly rely on ice-structuring proteins or nanomaterials to hinder the conversion of water into crystalline ice (Ih) under low temperatures. Here we report that the presence of minuscule mineral particles can significantly suppress the volume expansion of water upon freezing into ice. In particular, colloidal precipitates of calcite, a primary mineral accounting for ∼4 wt % of the Earth's crust and the most abundant biomineral on Earth, are able to reduce water expansion by 69% (from 8.4% to 2.6%) at 243 K. The mechanism of expansion suppression involves the formation of a continuous network of fairly ordered {"}ice-like{"} hydration waters that are bound to the surface of the mineral colloids at room temperature, and their concurrent crystallization through heterogeneous nucleation upon freezing, which confines the interstitial free water and refrains its volume expansion. These findings reveal the remarkable ability of common minerals to suppress a most ubiquitous phenomenon, water volume expansion upon freezing, and offer fresh insights into various fields such as biomineralization, hydrology, soil science, and lithology. {\textcopyright} 2026 The Authors. Published by American Chemical Society.",

author = "Hongkun Li and Yunchen Long and Junda Shen and Xinxue Tang and Jiahua Liu and Chong Wang and Binbin Zhou and Bo Li and Jing Zhong and Xiao Ma and Chunyi Zhi and Jian Lu and Li, {Yang Yang}",

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AU - Li, Hongkun

AU - Long, Yunchen

AU - Shen, Junda

AU - Tang, Xinxue

AU - Liu, Jiahua

AU - Wang, Chong

AU - Zhou, Binbin

AU - Li, Bo

AU - Zhong, Jing

AU - Ma, Xiao

AU - Zhi, Chunyi

AU - Lu, Jian

AU - Li, Yang Yang

PY - 2026/1/29

Y1 - 2026/1/29

N2 - The freezing behaviors of water are one of the most critical factors that define the formats of life and the landscapes on Earth. The current methods for regulating the freezing behaviors mainly rely on ice-structuring proteins or nanomaterials to hinder the conversion of water into crystalline ice (Ih) under low temperatures. Here we report that the presence of minuscule mineral particles can significantly suppress the volume expansion of water upon freezing into ice. In particular, colloidal precipitates of calcite, a primary mineral accounting for ∼4 wt % of the Earth's crust and the most abundant biomineral on Earth, are able to reduce water expansion by 69% (from 8.4% to 2.6%) at 243 K. The mechanism of expansion suppression involves the formation of a continuous network of fairly ordered "ice-like" hydration waters that are bound to the surface of the mineral colloids at room temperature, and their concurrent crystallization through heterogeneous nucleation upon freezing, which confines the interstitial free water and refrains its volume expansion. These findings reveal the remarkable ability of common minerals to suppress a most ubiquitous phenomenon, water volume expansion upon freezing, and offer fresh insights into various fields such as biomineralization, hydrology, soil science, and lithology. © 2026 The Authors. Published by American Chemical Society.

AB - The freezing behaviors of water are one of the most critical factors that define the formats of life and the landscapes on Earth. The current methods for regulating the freezing behaviors mainly rely on ice-structuring proteins or nanomaterials to hinder the conversion of water into crystalline ice (Ih) under low temperatures. Here we report that the presence of minuscule mineral particles can significantly suppress the volume expansion of water upon freezing into ice. In particular, colloidal precipitates of calcite, a primary mineral accounting for ∼4 wt % of the Earth's crust and the most abundant biomineral on Earth, are able to reduce water expansion by 69% (from 8.4% to 2.6%) at 243 K. The mechanism of expansion suppression involves the formation of a continuous network of fairly ordered "ice-like" hydration waters that are bound to the surface of the mineral colloids at room temperature, and their concurrent crystallization through heterogeneous nucleation upon freezing, which confines the interstitial free water and refrains its volume expansion. These findings reveal the remarkable ability of common minerals to suppress a most ubiquitous phenomenon, water volume expansion upon freezing, and offer fresh insights into various fields such as biomineralization, hydrology, soil science, and lithology. © 2026 The Authors. Published by American Chemical Society.

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Concurrent Formation of Ice Network within Mineral Colloids with Suppressed Volume Expansion

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