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Main Authors: Yedigaryan, Aram, Noor, Mohamed Yaseen, Kachan, Elena, Calderon, Gabriel, Hwang, Jinwoo, Chowdhury, Enam, Colombier, Jean-Philippe
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.16968
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author Yedigaryan, Aram
Noor, Mohamed Yaseen
Kachan, Elena
Calderon, Gabriel
Hwang, Jinwoo
Chowdhury, Enam
Colombier, Jean-Philippe
author_facet Yedigaryan, Aram
Noor, Mohamed Yaseen
Kachan, Elena
Calderon, Gabriel
Hwang, Jinwoo
Chowdhury, Enam
Colombier, Jean-Philippe
contents The crystallization of amorphous solids under ultrafast laser irradiation represents a paradigm of non-equilibrium phase transitions, where the interplay between electromagnetic energy localization and atomic-scale dynamics remains largely uncharted. By using a multiscale framework that couples Finite-Difference Time-Domain simulations of nonlinear light propagation with Molecular Dynamics of the atomic response, we demonstrate that field enhancement at nanopore interfaces confines laser energy and drives a rapid collapse of the surrounding matrix. In the silica structure containing a nanopore of 2 nm radius, corresponding to a porosity of approximately 7%, the enhanced local electromagnetic field led to a final equilibrium temperature 16% higher than for the 1-nm pore (1% porosity), and 20% higher than for the homogeneous medium. Particularly, the heterogeneous energy localization in the 2-nm-pore system created a preferential nucleation site within the dense glass network and led to the ultrafast formation of stishovite, a high-pressure crystalline phase of SiO2, on a sub-nanosecond timescale, significantly faster than in homogeneous silica at the same equilibrium temperature. Such accelerated crystallization enables the phase transition to outpace pressure relaxation, which would otherwise inhibit stishovite formation under identical thermal loading. These predictions align with experimental observations of laser-induced crystallization in confined geometries and establish nanopores as potent catalysts for controlling solid-state transformations via tailored electromagnetic hotspots.
format Preprint
id arxiv_https___arxiv_org_abs_2603_16968
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle From pore collapse to crystal growth: ultrafast laser-induced stishovite formation in nanoporous silica
Yedigaryan, Aram
Noor, Mohamed Yaseen
Kachan, Elena
Calderon, Gabriel
Hwang, Jinwoo
Chowdhury, Enam
Colombier, Jean-Philippe
Materials Science
The crystallization of amorphous solids under ultrafast laser irradiation represents a paradigm of non-equilibrium phase transitions, where the interplay between electromagnetic energy localization and atomic-scale dynamics remains largely uncharted. By using a multiscale framework that couples Finite-Difference Time-Domain simulations of nonlinear light propagation with Molecular Dynamics of the atomic response, we demonstrate that field enhancement at nanopore interfaces confines laser energy and drives a rapid collapse of the surrounding matrix. In the silica structure containing a nanopore of 2 nm radius, corresponding to a porosity of approximately 7%, the enhanced local electromagnetic field led to a final equilibrium temperature 16% higher than for the 1-nm pore (1% porosity), and 20% higher than for the homogeneous medium. Particularly, the heterogeneous energy localization in the 2-nm-pore system created a preferential nucleation site within the dense glass network and led to the ultrafast formation of stishovite, a high-pressure crystalline phase of SiO2, on a sub-nanosecond timescale, significantly faster than in homogeneous silica at the same equilibrium temperature. Such accelerated crystallization enables the phase transition to outpace pressure relaxation, which would otherwise inhibit stishovite formation under identical thermal loading. These predictions align with experimental observations of laser-induced crystallization in confined geometries and establish nanopores as potent catalysts for controlling solid-state transformations via tailored electromagnetic hotspots.
title From pore collapse to crystal growth: ultrafast laser-induced stishovite formation in nanoporous silica
topic Materials Science
url https://arxiv.org/abs/2603.16968