Multiscale geometrical and topological learning in the analysis of soft matter collective dynamics
Multiscale geometrical and topological learning in the analysis of soft matter collective dynamics
Understanding the behavior and evolution of a dynamical many-body system by analyzing patterns in their experimentally captured images is a promising method relevant for a variety of living and nonliving self-assembled systems. The arrays of moving liquid crystal skyrmions studied here are a representative example of hierarchically organized materials that exhibit complex spatiotemporal dynamics driven by multiscale processes. Joint geometric and topological data analysis (TDA) offers a powerful framework for investigating such systems by capturing the underlying structure of the data at multiple scales. In the TDA approach, we introduce the Ψ function, a robust numerical topological descriptor related to both the spatiotemporal changes in the size and shape of individual topological solitons and the emergence of regions with their different spatial organization. The geometric method based on the analysis of vector fields generated from images of skyrmion ensembles offers insights into the nonlinear physical mechanisms of the system's response to external stimuli and provides a basis for comparison with theoretical predictions. The methodology presented here is very general and can provide a characterization of system behavior both at the level of individual pattern-forming agents and as a whole, allowing one to relate the results of image data analysis to processes occurring in a physical, chemical, or biological system in the real world.
Orlova, Tetiana
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Membrillo Solis, Amaranta
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Sohn, Hayley R.O.
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Madeleine, Tristan
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D'Alessandro, Giampaolo
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Smalyukh, Ivan I.
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Kaczmarek, Malgosia
408ec59b-8dba-41c1-89d0-af846d1bf327
Brodzki, Jacek
b1fe25fd-5451-4fd0-b24b-c59b75710543
Orlova, Tetiana
7b190d43-4489-4d4f-89d9-75eec72030ae
Membrillo Solis, Amaranta
94b16293-285b-4bf0-a1e1-b590c6b8b50c
Sohn, Hayley R.O.
75c9a091-7048-4a78-a082-2655135458db
Madeleine, Tristan
e2b572ce-f77f-40d6-9b2f-9e581ca95944
D'Alessandro, Giampaolo
bad097e1-9506-4b6e-aa56-3e67a526e83b
Smalyukh, Ivan I.
8b732e4b-bf5b-4b4d-a296-21e91a1dfff6
Kaczmarek, Malgosia
408ec59b-8dba-41c1-89d0-af846d1bf327
Brodzki, Jacek
b1fe25fd-5451-4fd0-b24b-c59b75710543
Orlova, Tetiana, Membrillo Solis, Amaranta, Sohn, Hayley R.O., Madeleine, Tristan, D'Alessandro, Giampaolo, Smalyukh, Ivan I., Kaczmarek, Malgosia and Brodzki, Jacek
(2026)
Multiscale geometrical and topological learning in the analysis of soft matter collective dynamics.
Physical Review Materials, 10.
(doi:10.1103/dht2-w1gz).
Abstract
Understanding the behavior and evolution of a dynamical many-body system by analyzing patterns in their experimentally captured images is a promising method relevant for a variety of living and nonliving self-assembled systems. The arrays of moving liquid crystal skyrmions studied here are a representative example of hierarchically organized materials that exhibit complex spatiotemporal dynamics driven by multiscale processes. Joint geometric and topological data analysis (TDA) offers a powerful framework for investigating such systems by capturing the underlying structure of the data at multiple scales. In the TDA approach, we introduce the Ψ function, a robust numerical topological descriptor related to both the spatiotemporal changes in the size and shape of individual topological solitons and the emergence of regions with their different spatial organization. The geometric method based on the analysis of vector fields generated from images of skyrmion ensembles offers insights into the nonlinear physical mechanisms of the system's response to external stimuli and provides a basis for comparison with theoretical predictions. The methodology presented here is very general and can provide a characterization of system behavior both at the level of individual pattern-forming agents and as a whole, allowing one to relate the results of image data analysis to processes occurring in a physical, chemical, or biological system in the real world.
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dht2-w1gz
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Accepted/In Press date: 24 November 2025
e-pub ahead of print date: 9 January 2026
Identifiers
Local EPrints ID: 508068
URI: http://eprints.soton.ac.uk/id/eprint/508068
ISSN: 2475-9953
PURE UUID: 799f12a6-272a-4a39-8303-450bba393c25
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Date deposited: 12 Jan 2026 18:04
Last modified: 13 Jan 2026 03:07
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Contributors
Author:
Amaranta Membrillo Solis
Author:
Hayley R.O. Sohn
Author:
Tristan Madeleine
Author:
Ivan I. Smalyukh
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