Pattern formation on an ice surface

Zhihua Wang; Kwing So Choi; Shuguang Li; Chao Sun; Xuerui Mao

doi:10.1017/jfm.2025.10265

Pattern formation on an ice surface

Zhihua Wang, Kwing So Choi, Shuguang Li, Chao Sun, Xuerui Mao^*

^*Corresponding author for this work

Advanced Research Institute of Multidisciplinary Science

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

Abstract

A linear stability model based on a phase-field method is established to study the formation of ripples on the ice surface. The pattern on horizontal ice surfaces, e.g. glaciers and frozen lakes, is found to be originating from a gravity-driven instability by studying ice-water-air flows with a range of water and ice thicknesses. Contrary to gravity, surface tension and viscosity act to suppress the instability. The results demonstrate that a larger value of either water thickness or ice thickness corresponds to a longer dominant wavelength of the pattern, and a favourable wavelength of 90 mm is predicted, in agreement with observations from nature. Furthermore, the profiles of the most unstable perturbations are found to be with two peaks at the ice-water and water-air interfaces whose ratio decreases exponentially with the water thickness and wavenumber.

Original language	English
Article number	A35
Journal	Journal of Fluid Mechanics
Volume	1013
DOIs	https://doi.org/10.1017/jfm.2025.10265
Publication status	Published - 23 Jun 2025

Keywords

morphological instability
multiphase flow
pattern formation

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10.1017/jfm.2025.10265

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title = "Pattern formation on an ice surface",

abstract = "A linear stability model based on a phase-field method is established to study the formation of ripples on the ice surface. The pattern on horizontal ice surfaces, e.g. glaciers and frozen lakes, is found to be originating from a gravity-driven instability by studying ice-water-air flows with a range of water and ice thicknesses. Contrary to gravity, surface tension and viscosity act to suppress the instability. The results demonstrate that a larger value of either water thickness or ice thickness corresponds to a longer dominant wavelength of the pattern, and a favourable wavelength of 90 mm is predicted, in agreement with observations from nature. Furthermore, the profiles of the most unstable perturbations are found to be with two peaks at the ice-water and water-air interfaces whose ratio decreases exponentially with the water thickness and wavenumber.",

keywords = "morphological instability, multiphase flow, pattern formation",

author = "Zhihua Wang and Choi, \{Kwing So\} and Shuguang Li and Chao Sun and Xuerui Mao",

note = "Publisher Copyright: {\textcopyright} The Author(s), 2025. Published by Cambridge University Press.",

year = "2025",

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doi = "10.1017/jfm.2025.10265",

language = "English",

volume = "1013",

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TY - JOUR

T1 - Pattern formation on an ice surface

AU - Wang, Zhihua

AU - Choi, Kwing So

AU - Li, Shuguang

AU - Sun, Chao

AU - Mao, Xuerui

N1 - Publisher Copyright: © The Author(s), 2025. Published by Cambridge University Press.

PY - 2025/6/23

Y1 - 2025/6/23

N2 - A linear stability model based on a phase-field method is established to study the formation of ripples on the ice surface. The pattern on horizontal ice surfaces, e.g. glaciers and frozen lakes, is found to be originating from a gravity-driven instability by studying ice-water-air flows with a range of water and ice thicknesses. Contrary to gravity, surface tension and viscosity act to suppress the instability. The results demonstrate that a larger value of either water thickness or ice thickness corresponds to a longer dominant wavelength of the pattern, and a favourable wavelength of 90 mm is predicted, in agreement with observations from nature. Furthermore, the profiles of the most unstable perturbations are found to be with two peaks at the ice-water and water-air interfaces whose ratio decreases exponentially with the water thickness and wavenumber.

AB - A linear stability model based on a phase-field method is established to study the formation of ripples on the ice surface. The pattern on horizontal ice surfaces, e.g. glaciers and frozen lakes, is found to be originating from a gravity-driven instability by studying ice-water-air flows with a range of water and ice thicknesses. Contrary to gravity, surface tension and viscosity act to suppress the instability. The results demonstrate that a larger value of either water thickness or ice thickness corresponds to a longer dominant wavelength of the pattern, and a favourable wavelength of 90 mm is predicted, in agreement with observations from nature. Furthermore, the profiles of the most unstable perturbations are found to be with two peaks at the ice-water and water-air interfaces whose ratio decreases exponentially with the water thickness and wavenumber.

KW - morphological instability

KW - multiphase flow

KW - pattern formation

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DO - 10.1017/jfm.2025.10265

M3 - Article

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SN - 0022-1120

VL - 1013

JO - Journal of Fluid Mechanics

JF - Journal of Fluid Mechanics

M1 - A35

ER -

Pattern formation on an ice surface

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