Liquid water: obtaining the right answer for the right reasons

Proceedings of the Conference on High Performance Computing Networking, Storage and Analysis Pub Date : 2009-11-14 DOI:10.1145/1654059.1654127

E. Aprá, Alistair P. Rendell, R. Harrison, V. Tipparaju, W. A. Jong, S. Xantheas

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引用次数: 53

Abstract

Water is ubiquitous on our planet and plays an essential role in several key chemical and biological processes. Accurate models for water are crucial in understanding, controlling and predicting the physical and chemical properties of complex aqueous systems. Over the last few years we have been developing a molecular-level based approach for a macroscopic model for water that is based on the explicit description of the underlying intermolecular interactions between molecules in water clusters. In the absence of detailed experimental data for small water clusters, highly-accurate theoretical results are required to validate and parameterize model potentials. As an example of the benchmarks needed for the development of accurate models for the interaction between water molecules, for the most stable structure of (H2O)20 we ran a coupled-cluster calculation on the ORNL's Jaguar petaflop computer that used over 100 TB of memory for a sustained performance of 487 TFLOP/s (double precision) on 96,000 processors, lasting for 2 hours. By this summer we will have studied multiple structures of both (H2O)20 and (H2O)24 and completed basis set and other convergence studies and anticipate the sustained performance rising close to 1 PFLOP/s.

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液态水:以正确的理由得到正确的答案

水在我们的星球上无处不在，在几个关键的化学和生物过程中起着至关重要的作用。准确的水模型对于理解、控制和预测复杂水系统的物理和化学性质至关重要。在过去的几年里，我们一直在开发一种基于分子水平的方法，用于水的宏观模型，该模型基于对水簇中分子之间潜在的分子间相互作用的明确描述。在缺乏详细的小水团实验数据的情况下，需要高精度的理论结果来验证和参数化模型电位。作为开发水分子间相互作用精确模型所需的基准测试的一个例子，对于(H2O)20最稳定的结构，我们在ORNL的Jaguar petaflop计算机上运行了一个耦合集群计算，该计算机使用了超过100 TB的内存，在96,000个处理器上实现了487 TFLOP/s(双精度)的持续性能，持续了2小时。到今年夏天，我们将研究(H2O)20和(H2O)24的多种结构，并完成基础集和其他收敛性研究，并预计持续性能将接近1 PFLOP/s。

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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Proceedings of the Conference on High Performance Computing Networking, Storage and Analysis

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