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Learning complexity to guide light-induced self-organized nanopatterns

Materials Science 2023-10-23 v1 Optics

Abstract

Ultrafast laser irradiation can induce spontaneous self-organization of surfaces into dissipative structures with nanoscale reliefs. These surface patterns emerge from symmetry-breaking dynamical processes that occur in Rayleigh-B\'enard-like instabilities. In this study, we demonstrate that the coexistence and competition between surface patterns of different symmetries in two dimensions can be numerically unraveled using the stochastic generalized Swift-Hohenberg model. We originally propose a deep convolutional network to identify and learn the dominant modes that stabilize for a given bifurcation and quadratic model coefficients. The model is scale-invariant and has been calibrated on microscopy measurements using a physics-guided machine learning strategy. Our approach enables the identification of experimental irradiation conditions for a desired self-organization pattern. It can be applied generally to predict structure formation in situations where the underlying physics can be approximately described by a self-organization process and data is sparse and non-time series. Our work paves the way for supervised local manipulation of matter using timely-controlled optical fields in laser manufacturing.

Keywords

Cite

@article{arxiv.2310.13453,
  title  = {Learning complexity to guide light-induced self-organized nanopatterns},
  author = {Eduardo Brandao and Anthony Nakhoul and Stefan Duffner and Rémi Emonet and Florence Garrelie and Amaury Habrard and François Jacquenet and Florent Pigeon and Marc Sebban and Jean-Philippe Colombier},
  journal= {arXiv preprint arXiv:2310.13453},
  year   = {2023}
}
R2 v1 2026-06-28T12:56:46.521Z