Nanoscale Turing patterns in a bismuth monolayer

Yuki Fuseya; Hiroyasu Katsuno; Kamran Behnia; Aharon Kapitulnik

doi:10.1038/s41567-021-01288-y

Nanoscale Turing patterns in a bismuth monolayer

Yuki Fuseya
, Hiroyasu Katsuno
, Kamran Behnia
, Aharon Kapitulnik

École Polytechnique

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

Abstract

Turing’s reaction–diffusion theory of morphogenesis has been very successful for understanding macroscopic patterns within complex objects ranging from biological systems to sand dunes. However, Turing patterns on microscopic length scales are extremely rare. Here we show that a strained atomic bismuth monolayer assembled on the surface of NbSe₂—and subject to interatomic interactions and kinetics—displays Turing patterns. Our reaction–diffusion model produces stripe patterns with a period of five atoms (approximately 2 nm) and domain walls with Y-shaped junctions that bear a striking resemblance to what has been experimentally observed. Our work establishes that Turing patterns can occur at the atomic scale in a hard condensed-matter setting.

Original language	English
Pages (from-to)	1031-1036
Number of pages	6
Journal	Nature Physics
Volume	17
Issue number	9
DOIs	https://doi.org/10.1038/s41567-021-01288-y
Publication status	Published - 1 Sept 2021

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title = "Nanoscale Turing patterns in a bismuth monolayer",

abstract = "Turing{\textquoteright}s reaction–diffusion theory of morphogenesis has been very successful for understanding macroscopic patterns within complex objects ranging from biological systems to sand dunes. However, Turing patterns on microscopic length scales are extremely rare. Here we show that a strained atomic bismuth monolayer assembled on the surface of NbSe2—and subject to interatomic interactions and kinetics—displays Turing patterns. Our reaction–diffusion model produces stripe patterns with a period of five atoms (approximately 2 nm) and domain walls with Y-shaped junctions that bear a striking resemblance to what has been experimentally observed. Our work establishes that Turing patterns can occur at the atomic scale in a hard condensed-matter setting.",

author = "Yuki Fuseya and Hiroyasu Katsuno and Kamran Behnia and Aharon Kapitulnik",

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AU - Katsuno, Hiroyasu

AU - Behnia, Kamran

AU - Kapitulnik, Aharon

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N2 - Turing’s reaction–diffusion theory of morphogenesis has been very successful for understanding macroscopic patterns within complex objects ranging from biological systems to sand dunes. However, Turing patterns on microscopic length scales are extremely rare. Here we show that a strained atomic bismuth monolayer assembled on the surface of NbSe2—and subject to interatomic interactions and kinetics—displays Turing patterns. Our reaction–diffusion model produces stripe patterns with a period of five atoms (approximately 2 nm) and domain walls with Y-shaped junctions that bear a striking resemblance to what has been experimentally observed. Our work establishes that Turing patterns can occur at the atomic scale in a hard condensed-matter setting.

AB - Turing’s reaction–diffusion theory of morphogenesis has been very successful for understanding macroscopic patterns within complex objects ranging from biological systems to sand dunes. However, Turing patterns on microscopic length scales are extremely rare. Here we show that a strained atomic bismuth monolayer assembled on the surface of NbSe2—and subject to interatomic interactions and kinetics—displays Turing patterns. Our reaction–diffusion model produces stripe patterns with a period of five atoms (approximately 2 nm) and domain walls with Y-shaped junctions that bear a striking resemblance to what has been experimentally observed. Our work establishes that Turing patterns can occur at the atomic scale in a hard condensed-matter setting.

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DO - 10.1038/s41567-021-01288-y

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JO - Nature Physics

JF - Nature Physics

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ER -

Nanoscale Turing patterns in a bismuth monolayer

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