| INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
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| Simulation of Nanofilm Material Growth: a Comparison and Application ofMonte Carlo and Molecular Dynamics |
| YANG Ta1, MA Xiaobo2,*, HOU Junyi2, WANG Ning3, HE Lijun1
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1 Key Laboratory of Photovoltaic, School of Materials and New Energy, Ningxia University, Yinchuan 750021, China
2 State Key Laboratory of Rare Metal Special Materials, China Nonferrous Metal (Ningxia) Oriental Group Co., Ltd., Shizuishan 753000, Ningxia, China
3 Department of Basic Courses, Wuhan Donghu College, Wuhan 430212, China |
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Abstract Thin film materials represent a critical area of research within materials science. The rapid advancement of nanotechnology has led to a substantial reduction in its characteristic dimensions from tens of micrometers to just a few nanometers or even less. Due to the nanoscale effect, the thin film exhibits noveloptical, electrical, and magnetic properties, thereby attracting significant scientific interest. However, the conti-nued miniaturization of thin films presents considerable challenges in elucidating growth mechanisms and controlling their performance, primarily due to the inherent limitations of current characterization techniques. To overcome these challenges, computational methods have emerged as powerful tools for investigating thin film growth. This review provides a comprehensive overview of the application of Monte Carlo (MC) and molecular dynamics (MD) simulations, highlighting the respective strengths of each method in modeling atomic aggregation, surface morphology evolution, and structural formation mechanisms. MC simulations offer strong statistical capabilities for modeling large-scale systems and are particularly effective in capturing stochastic atomic aggregation behavior. In contrast, MD simulations provide detailed insight into atomic-scale dynamics over short time scales, enabling accurate representation of atomic trajectories and interatomic interactions. The integration of MC and MD approaches facilitates a multi-scale, multi-dimensional understanding of the complex processes in thin film growth. This combined computational framework not only enhances the fundamental understanding of thin film formation but also offers valuable theoretical and practical guidance for the rational design and fabrication of nanostructured materials.
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Received: 10 May 2026
Published:
Online: 2026-05-18
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2026, Vol. 40 
