Benchmarking Quantum Chemistry Methods in Calculations of Electronic Excitations

Supercomput. Front. Innov. Pub Date : 2018-12-01 DOI:10.14529/JSFI180405

B. Grigorenko, V. Mironov, Igor V. Polyakov, A. Nemukhin

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引用次数: 5

Abstract

Quantum chemistry methods are applied to obtain numerical solutions of the Schr¨odinger equation for molecular systems. Calculations of transitions between electronic states of large molecules present one of the greatest challenges in this field which require the use of supercomputer resources. In this work we describe the results of benchmark calculations of electronic excitation in the protein domains which were designed to engineer novel fluorescent markers operating in the near-infrared region. We demonstrate that such complex systems can be efficiently modeled with the hybrid qunatum mechanics/molecular mechanics approach (QM/MM) using the modern supercomputers. More specifically, the time-dependent density functional theory (TD-DFT) method was primarily tested with respect to its performance and accuracy. GAMESS (US) and NWChem software were benchmarked in direct and storage-based TDDFT calculations with the hybrid B3LYP density functional, both showing good scaling up to 32 nodes. We note that conventional SCF calculations greatly outperform direct SCF calculations for our test system. Accuracy of TD-DFT excitation energies was estimated by a comparison to the more accurate ab initio XMCQDPT2 method.

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电子激发计算中的基准量子化学方法

应用量子化学方法得到了分子体系薛定谔方程的数值解。计算大分子电子态之间的跃迁是该领域最大的挑战之一，需要使用超级计算机资源。在这项工作中，我们描述了蛋白质结构域电子激发的基准计算结果，这些计算旨在设计在近红外区域操作的新型荧光标记。我们证明了利用现代超级计算机可以有效地用量子力学/分子力学混合方法(QM/MM)对这类复杂系统进行建模。更具体地说，主要测试了时变密度泛函理论(TD-DFT)方法的性能和准确性。GAMESS (US)和NWChem软件在使用混合B3LYP密度函数的直接和基于存储的TDDFT计算中进行了基准测试，两者都显示出良好的扩展到32个节点。我们注意到，对于我们的测试系统，传统的SCF计算大大优于直接的SCF计算。通过与更精确的从头算XMCQDPT2方法的比较，估计了TD-DFT激发能的精度。

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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Supercomput. Front. Innov.

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