Phase separation explains a new class of self-organized spatial patterns in ecological systems

Quan-Xing Liu; Arjen Doelman; Vivi Rottschafer; Monique de Jager; Peter M. J. Herman; Max Rietkerk; Johan van de Koppel

doi:10.1073/pnas.1222339110

Phase separation explains a new class of self-organized spatial patterns in ecological systems

Quan-Xing Liu^*, Arjen Doelman, Vivi Rottschafer, Monique de Jager, Peter M. J. Herman, Max Rietkerk, Johan van de Koppel

^*Corresponding author for this work

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

Abstract

The origin of regular spatial patterns in ecological systems has long fascinated researchers. Turing's activator-inhibitor principle is considered the central paradigm to explain such patterns. According to this principle, local activation combined with long-range inhibition of growth and survival is an essential prerequisite for pattern formation. Here, we show that the physical principle of phase separation, solely based on density-dependent movement by organisms, represents an alternative class of self-organized pattern formation in ecology. Using experiments with self-organizing mussel beds, we derive an empirical relation between the speed of animal movement and local animal density. By incorporating this relation in a partial differential equation, we demonstrate that this model corresponds mathematically to the wellknown Cahn-Hilliard equation for phase separation in physics. Finally, we show that the predicted patterns match those found both in field observations and in our experiments. Our results reveal a principle for ecological self-organization, where phase separation rather than activation and inhibition processes drives spatial pattern formation.

Original language	English
Pages (from-to)	11905-11910
Number of pages	6
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	110
Issue number	29
DOIs	https://doi.org/10.1073/pnas.1222339110
Publication status	Published - 16 Jul 2013

Funding

We thank Franjo Weissing and Kurt E. Anderson for critical comments on the manuscript, reviewer Nigel Goldenfeld for suggestions, in particular for emphasizing the importance of the Lifshitz-Slyozov power law, and an anonymous reviewer for constructive comments. We also thank Aniek van der Berg for assisting with the laboratory experiments. This study was financially supported by The Netherlands Organization of Scientific Research through the National Programme Sea and Coastal Research Project WaddenEngine. The research of M. R. is supported by the European Research Area-Net on Complexity through the project "Resilience and Interaction of Networks in Ecology and Economics." The research of J.v.d.K. is supported by the Mosselwad Project, funded by the Waddenfonds and the Dutch Ministry of Infrastructure and the Environment.

Keywords

mussels
mathematical model
spatial self-organization
animal a ggregation
DIFFUSION-MODEL
MUSSEL BEDS
ECOSYSTEMS
GROWTH
POPULATION
MECHANISMS
VEGETATION
DISPERSAL
KINETICS

Access to Document

10.1073/pnas.1222339110

Embargoed Document

11905
Final published version, 1.1 MB
Embargo ends: 1/01/50
Request copy

Cite this

@article{446b6ef4c1d94c338a1040bc6a225ebe,

title = "Phase separation explains a new class of self-organized spatial patterns in ecological systems",

abstract = "The origin of regular spatial patterns in ecological systems has long fascinated researchers. Turing's activator-inhibitor principle is considered the central paradigm to explain such patterns. According to this principle, local activation combined with long-range inhibition of growth and survival is an essential prerequisite for pattern formation. Here, we show that the physical principle of phase separation, solely based on density-dependent movement by organisms, represents an alternative class of self-organized pattern formation in ecology. Using experiments with self-organizing mussel beds, we derive an empirical relation between the speed of animal movement and local animal density. By incorporating this relation in a partial differential equation, we demonstrate that this model corresponds mathematically to the wellknown Cahn-Hilliard equation for phase separation in physics. Finally, we show that the predicted patterns match those found both in field observations and in our experiments. Our results reveal a principle for ecological self-organization, where phase separation rather than activation and inhibition processes drives spatial pattern formation.",

keywords = "mussels, mathematical model, spatial self-organization, animal a ggregation, DIFFUSION-MODEL, MUSSEL BEDS, ECOSYSTEMS, GROWTH, POPULATION, MECHANISMS, VEGETATION, DISPERSAL, KINETICS",

author = "Quan-Xing Liu and Arjen Doelman and Vivi Rottschafer and {de Jager}, Monique and Herman, {Peter M. J.} and Max Rietkerk and {van de Koppel}, Johan",

year = "2013",

month = jul,

day = "16",

doi = "10.1073/pnas.1222339110",

language = "English",

volume = "110",

pages = "11905--11910",

journal = "Proceedings of the National Academy of Sciences of the United States of America",

issn = "0027-8424",

publisher = "National Academy of Sciences",

number = "29",

}

TY - JOUR

T1 - Phase separation explains a new class of self-organized spatial patterns in ecological systems

AU - Liu, Quan-Xing

AU - Doelman, Arjen

AU - Rottschafer, Vivi

AU - de Jager, Monique

AU - Herman, Peter M. J.

AU - Rietkerk, Max

AU - van de Koppel, Johan

PY - 2013/7/16

Y1 - 2013/7/16

N2 - The origin of regular spatial patterns in ecological systems has long fascinated researchers. Turing's activator-inhibitor principle is considered the central paradigm to explain such patterns. According to this principle, local activation combined with long-range inhibition of growth and survival is an essential prerequisite for pattern formation. Here, we show that the physical principle of phase separation, solely based on density-dependent movement by organisms, represents an alternative class of self-organized pattern formation in ecology. Using experiments with self-organizing mussel beds, we derive an empirical relation between the speed of animal movement and local animal density. By incorporating this relation in a partial differential equation, we demonstrate that this model corresponds mathematically to the wellknown Cahn-Hilliard equation for phase separation in physics. Finally, we show that the predicted patterns match those found both in field observations and in our experiments. Our results reveal a principle for ecological self-organization, where phase separation rather than activation and inhibition processes drives spatial pattern formation.

AB - The origin of regular spatial patterns in ecological systems has long fascinated researchers. Turing's activator-inhibitor principle is considered the central paradigm to explain such patterns. According to this principle, local activation combined with long-range inhibition of growth and survival is an essential prerequisite for pattern formation. Here, we show that the physical principle of phase separation, solely based on density-dependent movement by organisms, represents an alternative class of self-organized pattern formation in ecology. Using experiments with self-organizing mussel beds, we derive an empirical relation between the speed of animal movement and local animal density. By incorporating this relation in a partial differential equation, we demonstrate that this model corresponds mathematically to the wellknown Cahn-Hilliard equation for phase separation in physics. Finally, we show that the predicted patterns match those found both in field observations and in our experiments. Our results reveal a principle for ecological self-organization, where phase separation rather than activation and inhibition processes drives spatial pattern formation.

KW - mussels

KW - mathematical model

KW - spatial self-organization

KW - animal a ggregation

KW - DIFFUSION-MODEL

KW - MUSSEL BEDS

KW - ECOSYSTEMS

KW - GROWTH

KW - POPULATION

KW - MECHANISMS

KW - VEGETATION

KW - DISPERSAL

KW - KINETICS

U2 - 10.1073/pnas.1222339110

DO - 10.1073/pnas.1222339110

M3 - Article

SN - 0027-8424

VL - 110

SP - 11905

EP - 11910

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 - 29

ER -

Phase separation explains a new class of self-organized spatial patterns in ecological systems

Abstract

Funding

Keywords

Access to Document

Embargoed Document

Fingerprint

Cite this