Pattern formation by turbulent cascades

Xander M. de Wit; Michel Fruchart; Tali Khain; Federico Toschi; Vincenzo Vitelli

doi:10.1038/s41586-024-07074-z

Pattern formation by turbulent cascades

Xander M. de Wit
, Michel Fruchart
, Tali Khain
, Federico Toschi (Corresponding author)
, Vincenzo Vitelli (Corresponding author)

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

28 Citations (Scopus)

117 Downloads (Pure)

Abstract

Fully developed turbulence is a universal and scale-invariant chaotic state characterized by an energy cascade from large to small scales at which the cascade is eventually arrested by dissipation 1-6. Here we show how to harness these seemingly structureless turbulent cascades to generate patterns. Pattern formation entails a process of wavelength selection, which can usually be traced to the linear instability of a homogeneous state 7. By contrast, the mechanism we propose here is fully nonlinear. It is triggered by the non-dissipative arrest of turbulent cascades: energy piles up at an intermediate scale, which is neither the system size nor the smallest scales at which energy is usually dissipated. Using a combination of theory and large-scale simulations, we show that the tunable wavelength of these cascade-induced patterns can be set by a non-dissipative transport coefficient called odd viscosity, ubiquitous in chiral fluids ranging from bioactive to quantum systems 8-12. Odd viscosity, which acts as a scale-dependent Coriolis-like force, leads to a two-dimensionalization of the flow at small scales, in contrast with rotating fluids in which a two-dimensionalization occurs at large scales 4. Apart from odd viscosity fluids, we discuss how cascade-induced patterns can arise in natural systems, including atmospheric flows 13-19, stellar plasma such as the solar wind 20-22, or the pulverization and coagulation of objects or droplets in which mass rather than energy cascades 23-25.

Original language	English
Pages (from-to)	515-521
Number of pages	7
Journal	Nature
Volume	627
DOIs	https://doi.org/10.1038/s41586-024-07074-z
Publication status	Published - 21 Mar 2024

Funding

We thank L. Biferale and A. Schekochihin for discussions. We are grateful for the support of the Netherlands Organisation for Scientific Research (NWO) for the use of supercomputer facilities (Snellius) under grant no. 2021.035. This publication is part of the project \u2018Shaping turbulence with smart particles\u2019 with project no. OCENW.GROOT.2019.031 of the research programme Open Competitie ENW XL that is (partly) financed by the Dutch Research Council (NWO). M.F. acknowledges partial support from the National Science Foundation under grant no. DMR-2118415, a Kadanoff-Rice fellowship funded by the National Science Foundation under award no. DMR-2011854 and the Simons Foundation. T.K. acknowledges partial support from the National Science Foundation Graduate Research Fellowship under grant no. 1746045. V.V. acknowledges partial support from the Army Research Office under grant nos. W911NF-22-2-0109 and W911NF-23-1-0212 and the Theory in Biology program of the Chan Zuckerberg Initiative. M.F. and V.V. acknowledge partial support from the France Chicago centre through a FACCTS grant. This research was partly supported by the National Science Foundation through the Center for Living Systems (grant no. 2317138). We thank L. Biferale\u00A0and A.\u00A0Schekochihin for discussions. We are grateful for the support of the Netherlands Organisation for Scientific Research (NWO) for the use of supercomputer facilities (Snellius) under grant no. 2021.035. This publication is part of the project \u2018Shaping turbulence with smart particles\u2019 with project no. OCENW.GROOT.2019.031 of the research programme Open Competitie ENW XL that is (partly) financed by the Dutch Research Council (NWO). M.F. acknowledges partial support from the National Science Foundation under grant no. DMR-2118415, a Kadanoff-Rice fellowship funded by the National Science Foundation under award no. DMR-2011854 and the Simons Foundation. T.K. acknowledges partial support from the National Science Foundation Graduate Research Fellowship under grant no. 1746045. V.V. acknowledges partial support from the Army Research Office under grant nos. W911NF-22-2-0109 and W911NF-23-1-0212\u00A0and the Theory in Biology program of the Chan Zuckerberg Initiative. M.F. and V.V. acknowledge partial support from the France Chicago centre through a FACCTS grant. This research was partly supported by the National Science Foundation through the Center for Living Systems (grant no. 2317138).

Access to Document

10.1038/s41586-024-07074-zLicence: CC BY

pdfFinal published version, 4.83 MBLicence: CC BY

Cite this

@article{d46e96a32f1142cd90acf2ca5e9279a9,

title = "Pattern formation by turbulent cascades",

abstract = "Fully developed turbulence is a universal and scale-invariant chaotic state characterized by an energy cascade from large to small scales at which the cascade is eventually arrested by dissipation 1-6. Here we show how to harness these seemingly structureless turbulent cascades to generate patterns. Pattern formation entails a process of wavelength selection, which can usually be traced to the linear instability of a homogeneous state 7. By contrast, the mechanism we propose here is fully nonlinear. It is triggered by the non-dissipative arrest of turbulent cascades: energy piles up at an intermediate scale, which is neither the system size nor the smallest scales at which energy is usually dissipated. Using a combination of theory and large-scale simulations, we show that the tunable wavelength of these cascade-induced patterns can be set by a non-dissipative transport coefficient called odd viscosity, ubiquitous in chiral fluids ranging from bioactive to quantum systems 8-12. Odd viscosity, which acts as a scale-dependent Coriolis-like force, leads to a two-dimensionalization of the flow at small scales, in contrast with rotating fluids in which a two-dimensionalization occurs at large scales 4. Apart from odd viscosity fluids, we discuss how cascade-induced patterns can arise in natural systems, including atmospheric flows 13-19, stellar plasma such as the solar wind 20-22, or the pulverization and coagulation of objects or droplets in which mass rather than energy cascades 23-25. ",

author = "\{de Wit\}, \{Xander M.\} and Michel Fruchart and Tali Khain and Federico Toschi and Vincenzo Vitelli",

year = "2024",

month = mar,

day = "21",

doi = "10.1038/s41586-024-07074-z",

language = "English",

volume = "627",

pages = "515--521",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Research",

}

TY - JOUR

T1 - Pattern formation by turbulent cascades

AU - de Wit, Xander M.

AU - Fruchart, Michel

AU - Khain, Tali

AU - Toschi, Federico

AU - Vitelli, Vincenzo

PY - 2024/3/21

Y1 - 2024/3/21

N2 - Fully developed turbulence is a universal and scale-invariant chaotic state characterized by an energy cascade from large to small scales at which the cascade is eventually arrested by dissipation 1-6. Here we show how to harness these seemingly structureless turbulent cascades to generate patterns. Pattern formation entails a process of wavelength selection, which can usually be traced to the linear instability of a homogeneous state 7. By contrast, the mechanism we propose here is fully nonlinear. It is triggered by the non-dissipative arrest of turbulent cascades: energy piles up at an intermediate scale, which is neither the system size nor the smallest scales at which energy is usually dissipated. Using a combination of theory and large-scale simulations, we show that the tunable wavelength of these cascade-induced patterns can be set by a non-dissipative transport coefficient called odd viscosity, ubiquitous in chiral fluids ranging from bioactive to quantum systems 8-12. Odd viscosity, which acts as a scale-dependent Coriolis-like force, leads to a two-dimensionalization of the flow at small scales, in contrast with rotating fluids in which a two-dimensionalization occurs at large scales 4. Apart from odd viscosity fluids, we discuss how cascade-induced patterns can arise in natural systems, including atmospheric flows 13-19, stellar plasma such as the solar wind 20-22, or the pulverization and coagulation of objects or droplets in which mass rather than energy cascades 23-25.

AB - Fully developed turbulence is a universal and scale-invariant chaotic state characterized by an energy cascade from large to small scales at which the cascade is eventually arrested by dissipation 1-6. Here we show how to harness these seemingly structureless turbulent cascades to generate patterns. Pattern formation entails a process of wavelength selection, which can usually be traced to the linear instability of a homogeneous state 7. By contrast, the mechanism we propose here is fully nonlinear. It is triggered by the non-dissipative arrest of turbulent cascades: energy piles up at an intermediate scale, which is neither the system size nor the smallest scales at which energy is usually dissipated. Using a combination of theory and large-scale simulations, we show that the tunable wavelength of these cascade-induced patterns can be set by a non-dissipative transport coefficient called odd viscosity, ubiquitous in chiral fluids ranging from bioactive to quantum systems 8-12. Odd viscosity, which acts as a scale-dependent Coriolis-like force, leads to a two-dimensionalization of the flow at small scales, in contrast with rotating fluids in which a two-dimensionalization occurs at large scales 4. Apart from odd viscosity fluids, we discuss how cascade-induced patterns can arise in natural systems, including atmospheric flows 13-19, stellar plasma such as the solar wind 20-22, or the pulverization and coagulation of objects or droplets in which mass rather than energy cascades 23-25.

UR - https://www.scopus.com/pages/publications/85188239957

U2 - 10.1038/s41586-024-07074-z

DO - 10.1038/s41586-024-07074-z

M3 - Article

C2 - 38509279

AN - SCOPUS:85188239957

SN - 0028-0836

VL - 627

SP - 515

EP - 521

JO - Nature

JF - Nature

ER -

Pattern formation by turbulent cascades

Abstract

Funding

Access to Document

Other files and links

Fingerprint

Repository for: "Pattern formation by turbulent cascades"

Cite this

Pattern formation by turbulent cascades

Abstract

Funding

Access to Document

Other files and links

Fingerprint

Datasets

Repository for: "Pattern formation by turbulent cascades"

Cite this