GPU-Accelerated Large-Scale Excited-State Simulation Based on Divide-and-Conquer Time-Dependent Density-Functional Tight-Binding

被引：24

作者：

Yoshikawa, Takeshi ^{[1
]}

Komoto, Nana ^{[2
]}

Nishimura, Yoshifumi ^{[1
]}

Nakai, Hiromi ^{[1
,2
,3
]}

机构：

[1] Waseda Univ, Waseda Res Inst Sci & Engn, Shinjuku Ku, 3-4-1 Okubo, Tokyo 1698555, Japan

[2] Waseda Univ, Sch Adv Sci & Engn, Dept Chem & Biochem, Shinjuku Ku, 3-4-1 Okubo, Tokyo 1698555, Japan

[3] Kyoto Univ, ESICB, Kyoto 6158520, Japan

来源：

JOURNAL OF COMPUTATIONAL CHEMISTRY | 2019年 / 40卷 / 31期

基金：

日本学术振兴会;

关键词：

linear scaling; excited-state theory; time-dependent density-functional tight-binding method; divide-and-conquer method; graphical processor unit; GRAPHICAL PROCESSING UNITS; CONFIGURATION-INTERACTION SINGLES; QUANTUM-CHEMISTRY CALCULATIONS; REPULSION INTEGRAL EVALUATION; SHELL SYSTEMS IMPLEMENTATION; MOLECULAR TAILORING APPROACH; COUPLED-CLUSTER; ELECTRONIC-STRUCTURE; ENERGY; PRECISION;

D O I：

10.1002/jcc.26053

中图分类号：

O6 [化学];

学科分类号：

0703 ;

摘要：

The present study implemented the divide-and-conquer time-dependent density-functional tight-binding (DC-TDDFTB) code on a graphical processing unit (GPU). The DC method, which is a linear-scaling scheme, divides a total system into several fragments. By separately solving local equations in individual fragments, the DC method could reduce slow central processing unit (CPU)-GPU memory access, as well as computational cost, and avoid shortfalls of GPU memory. Numerical applications confirmed that the present code on GPU significantly accelerated the TDDFTB calculations, while maintaining accuracy. Furthermore, the DC-TDDFTB simulation of 2-acetylindan-1,3-dione displays excited-state intramolecular proton transfer and provides reasonable absorption and fluorescence energies with the corresponding experimental values. (c) 2019 Wiley Periodicals, Inc.

引用

页码：2778 / 2786

页数：9

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