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Main Authors: Fang, Yuan, Demirel, Ipen, Zhang, Xiaopu, Shao, Yuchuan, Shao, Jianda, Boland, John J.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.01920
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author Fang, Yuan
Demirel, Ipen
Zhang, Xiaopu
Shao, Yuchuan
Shao, Jianda
Boland, John J.
author_facet Fang, Yuan
Demirel, Ipen
Zhang, Xiaopu
Shao, Yuchuan
Shao, Jianda
Boland, John J.
contents The behavior of surface triple junctions (STJ) at emergent grain boundaries on free surfaces is critical to the microstructure evolution, and therefore to the stability of the next generation interconnect. Yet,despite this significant importance, its lowest-energy structure and local stress have remained persistently unknown. Here, we fill this critical gap through high-resolution experimental mapping of the local surface deformation at STJ, the analysis of the local structure and stress relaxation, and ergodic searching metastable structures. We establish the zipped Y-shaped notch as the universal lowest-energy structures. This energetic preference was well explained by the distinctive local stress mechanism and was excellently verified with machine learning methods for a wide range of boundaries. By revealing the elusive thermodynamics of STJs, our findings advance the research field by redefining the energetic framework for capillary driven structure evolution and providing foundation for understanding kinetically diffusive deformation and for engineering thin-film interconnects and related materials.
format Preprint
id arxiv_https___arxiv_org_abs_2603_01920
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Pathway to lowest-energy structures and stress relaxation for the surface triple junction verified by machine learning
Fang, Yuan
Demirel, Ipen
Zhang, Xiaopu
Shao, Yuchuan
Shao, Jianda
Boland, John J.
Materials Science
The behavior of surface triple junctions (STJ) at emergent grain boundaries on free surfaces is critical to the microstructure evolution, and therefore to the stability of the next generation interconnect. Yet,despite this significant importance, its lowest-energy structure and local stress have remained persistently unknown. Here, we fill this critical gap through high-resolution experimental mapping of the local surface deformation at STJ, the analysis of the local structure and stress relaxation, and ergodic searching metastable structures. We establish the zipped Y-shaped notch as the universal lowest-energy structures. This energetic preference was well explained by the distinctive local stress mechanism and was excellently verified with machine learning methods for a wide range of boundaries. By revealing the elusive thermodynamics of STJs, our findings advance the research field by redefining the energetic framework for capillary driven structure evolution and providing foundation for understanding kinetically diffusive deformation and for engineering thin-film interconnects and related materials.
title Pathway to lowest-energy structures and stress relaxation for the surface triple junction verified by machine learning
topic Materials Science
url https://arxiv.org/abs/2603.01920