Ice needles weave patterns of stones in freezing landscapes

Anyuan Li; Norikazu Matsuoka; Fujun Niu; Jing Chen; Zhenpeng Ge; Wensi Hu; Desheng Li; Bernard Hallet; Johan van de Koppel; Nigel Goldenfeld; Quan Xing Liu

doi:10.1073/pnas.2110670118

Ice needles weave patterns of stones in freezing landscapes

Anyuan Li, Norikazu Matsuoka, Fujun Niu, Jing Chen, Zhenpeng Ge, Wensi Hu, Desheng Li, Bernard Hallet, Johan van de Koppel, Nigel Goldenfeld, Quan Xing Liu

Physics

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

Abstract

Patterned ground, defined by the segregation of stones in soil according to size, is one of the most strikingly self-organized characteristics of polar and high-alpine landscapes. The presence of such patterns on Mars has been proposed as evidence for the past presence of surface liquid water. Despite their ubiquity, the dearth of quantitative field data on the patterns and their slow dynamics have hindered fundamental understanding of the pattern formation mechanisms. Here, we use laboratory experiments to show that stone transport is strongly dependent on local stone concentration and the height of ice needles, leading effectively to pattern formation driven by needle ice activity. Through numerical simulations, theory, and experiments, we show that the nonlinear amplification of long wavelength instabilities leads to self-similar dynamics that resemble phase separation patterns in binary alloys, characterized by scaling laws and spatial structure formation. Our results illustrate insights to be gained into patterns in landscapes by viewing the pattern formation through the lens of phase separation. Moreover, they may help interpret spatial structures that arise on diverse planetary landscapes, including ground patterns recently examined using the rover Curiosity on Mars.

Original language	English (US)
Article number	e2110670118
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	118
Issue number	40
Early online date	Sep 30 2021
DOIs	https://doi.org/10.1073/pnas.2110670118
State	Published - Oct 5 2021

Keywords

Freezing soils
Ice needles
Periglacial landform
Phase separation
Sorted patterned ground

ASJC Scopus subject areas

General

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10.1073/pnas.2110670118License: CC BY-NC-ND

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@article{ac567df39be543d996859ad1bca88aa2,

title = "Ice needles weave patterns of stones in freezing landscapes",

abstract = "Patterned ground, defined by the segregation of stones in soil according to size, is one of the most strikingly self-organized characteristics of polar and high-alpine landscapes. The presence of such patterns on Mars has been proposed as evidence for the past presence of surface liquid water. Despite their ubiquity, the dearth of quantitative field data on the patterns and their slow dynamics have hindered fundamental understanding of the pattern formation mechanisms. Here, we use laboratory experiments to show that stone transport is strongly dependent on local stone concentration and the height of ice needles, leading effectively to pattern formation driven by needle ice activity. Through numerical simulations, theory, and experiments, we show that the nonlinear amplification of long wavelength instabilities leads to self-similar dynamics that resemble phase separation patterns in binary alloys, characterized by scaling laws and spatial structure formation. Our results illustrate insights to be gained into patterns in landscapes by viewing the pattern formation through the lens of phase separation. Moreover, they may help interpret spatial structures that arise on diverse planetary landscapes, including ground patterns recently examined using the rover Curiosity on Mars.",

keywords = "Freezing soils, Ice needles, Periglacial landform, Phase separation, Sorted patterned ground",

author = "Anyuan Li and Norikazu Matsuoka and Fujun Niu and Jing Chen and Zhenpeng Ge and Wensi Hu and Desheng Li and Bernard Hallet and {van de Koppel}, Johan and Nigel Goldenfeld and Liu, {Quan Xing}",

note = "ACKNOWLEDGMENTS. We thank Wei Lu, Haobo Yang, Binqi Liu, Luming Fang, and Yunya Wang for assistance with preliminary tracking of stone movement in images, Purba Chatterjee for critical comments, and Kang Zhang for pyOpenCL code assistance. This work was supported by the Second Tibetan Plateau Scientific Expedition and Research program (Grant No. 2019QZKK0905), Japan Society for the Promotion of Science KAKENHI Grant No. 20K01138, the National Natural Science Foundation of China (Grant Nos. 41801043, 41676084, and 32061143014), and the Strategic Priority Research Program of the Chinese Academy of Sciences (Grant No. XDA19070504). A.L. gladly acknowledges the postdoctoral scholarship from the China Scholarship Council for supporting this work.",

year = "2021",

month = oct,

day = "5",

doi = "10.1073/pnas.2110670118",

language = "English (US)",

volume = "118",

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T1 - Ice needles weave patterns of stones in freezing landscapes

AU - Li, Anyuan

AU - Matsuoka, Norikazu

AU - Niu, Fujun

AU - Chen, Jing

AU - Ge, Zhenpeng

AU - Hu, Wensi

AU - Li, Desheng

AU - Hallet, Bernard

AU - van de Koppel, Johan

AU - Goldenfeld, Nigel

AU - Liu, Quan Xing

N1 - ACKNOWLEDGMENTS. We thank Wei Lu, Haobo Yang, Binqi Liu, Luming Fang, and Yunya Wang for assistance with preliminary tracking of stone movement in images, Purba Chatterjee for critical comments, and Kang Zhang for pyOpenCL code assistance. This work was supported by the Second Tibetan Plateau Scientific Expedition and Research program (Grant No. 2019QZKK0905), Japan Society for the Promotion of Science KAKENHI Grant No. 20K01138, the National Natural Science Foundation of China (Grant Nos. 41801043, 41676084, and 32061143014), and the Strategic Priority Research Program of the Chinese Academy of Sciences (Grant No. XDA19070504). A.L. gladly acknowledges the postdoctoral scholarship from the China Scholarship Council for supporting this work.

PY - 2021/10/5

Y1 - 2021/10/5

N2 - Patterned ground, defined by the segregation of stones in soil according to size, is one of the most strikingly self-organized characteristics of polar and high-alpine landscapes. The presence of such patterns on Mars has been proposed as evidence for the past presence of surface liquid water. Despite their ubiquity, the dearth of quantitative field data on the patterns and their slow dynamics have hindered fundamental understanding of the pattern formation mechanisms. Here, we use laboratory experiments to show that stone transport is strongly dependent on local stone concentration and the height of ice needles, leading effectively to pattern formation driven by needle ice activity. Through numerical simulations, theory, and experiments, we show that the nonlinear amplification of long wavelength instabilities leads to self-similar dynamics that resemble phase separation patterns in binary alloys, characterized by scaling laws and spatial structure formation. Our results illustrate insights to be gained into patterns in landscapes by viewing the pattern formation through the lens of phase separation. Moreover, they may help interpret spatial structures that arise on diverse planetary landscapes, including ground patterns recently examined using the rover Curiosity on Mars.

AB - Patterned ground, defined by the segregation of stones in soil according to size, is one of the most strikingly self-organized characteristics of polar and high-alpine landscapes. The presence of such patterns on Mars has been proposed as evidence for the past presence of surface liquid water. Despite their ubiquity, the dearth of quantitative field data on the patterns and their slow dynamics have hindered fundamental understanding of the pattern formation mechanisms. Here, we use laboratory experiments to show that stone transport is strongly dependent on local stone concentration and the height of ice needles, leading effectively to pattern formation driven by needle ice activity. Through numerical simulations, theory, and experiments, we show that the nonlinear amplification of long wavelength instabilities leads to self-similar dynamics that resemble phase separation patterns in binary alloys, characterized by scaling laws and spatial structure formation. Our results illustrate insights to be gained into patterns in landscapes by viewing the pattern formation through the lens of phase separation. Moreover, they may help interpret spatial structures that arise on diverse planetary landscapes, including ground patterns recently examined using the rover Curiosity on Mars.

KW - Freezing soils

KW - Ice needles

KW - Periglacial landform

KW - Phase separation

KW - Sorted patterned ground

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JO - Proceedings of the National Academy of Sciences of the United States of America

JF - Proceedings of the National Academy of Sciences of the United States of America

IS - 40

M1 - e2110670118

ER -

Ice needles weave patterns of stones in freezing landscapes

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