Large-scale atomistic simulations of nanostructured materials based on divide-and-conquer density functional theory

F. Shimojo; S. Ohmura; A. Nakano; R. K. Kalia; P. Vashishta

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Large-scale atomistic simulations of nanostructured materials based on divide-and-conquer density functional theory

机译：基于分治法密度泛函理论的纳米结构材料的大规模原子模拟

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A linear-scaling algorithm based on a divide-and-conquer (DC) scheme is designed to perform large-scale molecular-dynamics simulations, in which interatomic forces are computed quantum mechanically in the framework of the density functional theory (DFT). This scheme is applied to the thermite reaction at an Al/Fe2O3 interface. It is found that mass diffusion and reaction rate at the interface are enhanced by a concerted metal-oxygen flip mechanism. Preliminary simulations are carried out for an aluminum particle in water based on the conventional DFT, as a target system for large-scale DC-DFT simulations. A pair of Lewis acid and base sites on the aluminum surface preferentially catalyzes hydrogen production in a low activation-barrier mechanism found in the simulations

机译：设计了一种基于分而治之（DC）方案的线性缩放算法，以执行大规模的分子动力学模拟，其中原子间力在密度泛函理论（DFT）的框架内以量子力学方式进行计算。该方案适用于在Al / Fe2O3界面的铝热反应。发现通过协调的金属-氧气翻转机制提高了界面处的质量扩散和反应速率。作为常规DC-DFT模拟的目标系统，基于常规DFT对水中的铝颗粒进行了初步模拟。铝表面上的一对路易斯酸和碱位点优先以模拟中发现的低活化势垒机制催化氢的产生

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《EPJ Web of Conferences》 |2011年第13期|共6页
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F. Shimojo; S. Ohmura; A. Nakano; R. K. Kalia; P. Vashishta;
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1. Large-scale atomistic simulations of nanostructured materials based on divide-and-conquer density functional theory [J] . F. Shimojo, S. Ohmura, A. Nakano, The European Physical Journal - Special Topics . 2011,第1期

机译：基于分治法密度泛函理论的纳米结构材料的大规模原子模拟
2. Large-scale atomistic simulations of nanostructured materials based on divide-and-conquer density functional theory [J] . F. Shimojo, S. Ohmura, A. Nakano, The European physical journal: Special topics . 2011,第Null期

机译：基于分治法密度泛函理论的纳米结构材料的大规模原子模拟
3. Large-Scale Molecular Dynamics Simulation for Ground and Excited States Based on Divide-and-Conquer Long-Range Corrected Density-Functional Tight-Binding Method [J] . Komoto Nana, Yoshikawa Takeshi, Nishimura Yoshifumi, Journal of chemical theory and computation: JCTC . 2020,第4期

机译：基于划分的串串远程校正密度函数紧绑定方法的地面和兴奋状态大规模分子动力学模拟
4. Large-scale atomistic simulation of nanostructured materials on parallel computers [C] . Priya Vashishta, Martina E. Bachlechner, Timothy J. Campbell, Minerals, Metals and Materials Society . 2000

机译：平行计算机上纳米结构材料的大规模原子模拟
5. Atomistic simulations to study magnetic, mechanical, and thermal properties of materials using density functional theory and semi-empirical methods. [D] . Moitra, Amitava. 2010

机译：使用密度泛函理论和半经验方法进行原子模拟，以研究材料的磁，机械和热性能。
6. Rheology of colloidal suspensions in confined flow: Treatment of hydrodynamic interactions in particle-based simulations inspired by dynamical density functional theory [O] . Zahera Jabeen, Hsiu-Yu Yu, David M. Eckmann, -1

机译：受限流动中胶体悬浮液的流变学：在基于粒子的模拟中受动力密度泛函理论启发处理流体动力相互作用
7. Large-scale atomistic simulations of nanostructured materials based on divide-and-conquer density functional theory [O] . F. Shimojo, S. Ohmura, A. Nakano, 2011

机译：基于划分征管密度函数理论的纳米结构材料大规模原子模拟

Large-scale atomistic simulations of nanostructured materials based on divide-and-conquer density functional theory

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