Search:
Match:
3 results
Research Paper#Computational Materials Science, Crystal Structure Prediction, Machine Learning🔬 ResearchAnalyzed: Jan 3, 2026 08:37

SSCHA-based Evolutionary Crystal Structure Prediction with Quantum Nuclear Motion

Published:Dec 31, 2025 13:17
1 min read
ArXiv

Analysis

This paper addresses the challenge of accurate crystal structure prediction (CSP) at finite temperatures, particularly for systems with light atoms where quantum anharmonic effects are significant. It integrates machine-learned interatomic potentials (MLIPs) with the stochastic self-consistent harmonic approximation (SSCHA) to enable evolutionary CSP on the quantum anharmonic free-energy landscape. The study compares two MLIP approaches (active-learning and universal) using LaH10 as a test case, demonstrating the importance of including quantum anharmonicity for accurate stability rankings, especially at high temperatures. This work extends the applicability of CSP to systems where quantum nuclear motion and anharmonicity are dominant, which is a significant advancement.
Reference

Including quantum anharmonicity simplifies the free-energy landscape and is essential for correct stability rankings, that is especially important for high-temperature phases that could be missed in classical 0 K CSP.

PermalinkArXiv
Research Paper#Materials Science, Superconductivity, Radiation Damage, Machine Learning🔬 ResearchAnalyzed: Jan 3, 2026 09:29

Machine-Learned Potentials for Radiation Damage in Superconductors

Published:Dec 30, 2025 19:21
1 min read
ArXiv

Analysis

This paper addresses the critical need for accurate modeling of radiation damage in high-temperature superconductors (HTS), particularly YBa2Cu3O7-δ (YBCO), which is crucial for applications in fusion reactors. The authors leverage machine-learned interatomic potentials (ACE and tabGAP) to overcome limitations of existing empirical models, especially in describing oxygen-deficient YBCO compositions. The study's significance lies in its ability to predict radiation damage with higher fidelity, providing insights into defect production, cascade evolution, and the formation of amorphous regions. This is important for understanding the performance and durability of HTS tapes in harsh radiation environments.
Reference

Molecular dynamics simulations of 5 keV cascades predict enhanced peak defect production and recombination relative to a widely used empirical potential, indicating different cascade evolution.

PermalinkArXiv
Research#Materials Science🔬 ResearchAnalyzed: Jan 10, 2026 10:15

Accelerated Simulation: AI-Driven Interatomic Potential for MoS2 Epitaxial Growth

Published:Dec 17, 2025 20:26
1 min read
ArXiv

Analysis

This research highlights the application of machine learning to accelerate materials science simulations, a significant development for predictive modeling. The study's focus on MoS2 epitaxial growth demonstrates practical impact in semiconductor research.
Reference

The research focuses on the development of an ultra-fast, machine-learned interatomic potential for simulating the epitaxial growth of MoS2.

PermalinkArXiv