CUDA code to generate computational models and predict mechanical properties for metallic surface nanocoatings

IF 1.3 Q3 COMPUTER SCIENCE, SOFTWARE ENGINEERING Software Impacts Pub Date : 2024-05-01 DOI:10.1016/j.simpa.2024.100645

M. Bedolla-Hernández , F.J. Sánchez-Ruiz , G. Rosano-Ortega , J. Bedolla-Hernández , P.S. Schabes-Retchkiman , C.A. Vega-Lebrún , E. Vargas-Viveros

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Abstract

The article presents an open-access code, written in CUDA® and C++ programming language, applicable for generating computational models of nanostructured surface coatings deposited by electrodeposition. The code uses the Schrödinger equation, energy potentials, and electrochemistry as a theoretical basis to determine the deposition and electrodeposition energies, allowing the prediction of the formation and growth of these coatings. Likewise, the parameter variation enabled within the code provides for determining the main electrodeposition parameters (voltage, current, concentration, and residence time) for experimental depositions. The code can be easily implemented for any metallic coating-substrate arrangement where the filler material is nanomaterials.

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生成计算模型并预测金属表面纳米涂层机械性能的 CUDA 代码

文章介绍了一种用 CUDA® 和 C++ 编程语言编写的开放存取代码，适用于生成通过电沉积沉积的纳米结构表面涂层的计算模型。该代码以薛定谔方程、能势和电化学为理论基础，确定沉积和电沉积能量，从而预测这些涂层的形成和生长。同样，代码中启用的参数变化功能可确定实验沉积的主要电沉积参数（电压、电流、浓度和停留时间）。该代码可轻松应用于填充材料为纳米材料的任何金属涂层-基底排列。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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