Highly Accurate Real-space Electron Densities with Neural Networks

arXiv - PHYS - Chemical Physics Pub Date : 2024-09-02 DOI:arxiv-2409.01306

Lixue Cheng, P. Bernát Szabó, Zeno Schätzle, Derk Kooi, Jonas Köhler, Klaas J. H. Giesbertz, Frank Noé, Jan Hermann, Paola Gori-Giorgi, Adam Foster

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Abstract

Variational ab-initio methods in quantum chemistry stand out among other methods in providing direct access to the wave function. This allows in principle straightforward extraction of any other observable of interest, besides the energy, but in practice this extraction is often technically difficult and computationally impractical. Here, we consider the electron density as a central observable in quantum chemistry and introduce a novel method to obtain accurate densities from real-space many-electron wave functions by representing the density with a neural network that captures known asymptotic properties and is trained from the wave function by score matching and noise-contrastive estimation. We use variational quantum Monte Carlo with deep-learning ans\"atze (deep QMC) to obtain highly accurate wave functions free of basis set errors, and from them, using our novel method, correspondingly accurate electron densities, which we demonstrate by calculating dipole moments, nuclear forces, contact densities, and other density-based properties.

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利用神经网络实现高精度实空间电子密度

量子化学中的变分自证方法与其他方法不同，它可以直接获取波函数。这在原理上允许直接提取除能量之外的任何其他感兴趣的观测值，但在实践中，这种提取往往在技术上是困难的，在计算上也是不切实际的。在这里，我们将电子密度视为量子化学中的核心观测指标，并介绍了一种从实空多电子波函数中获得精确密度的新方法，即用神经网络来表示密度，该神经网络捕捉已知的渐近特性，并通过分数匹配和噪声对比估计从波函数中训练出来。我们使用具有深度学习能力的变分量子蒙特卡洛（deep QMC）来获得没有基集误差的高精度波函数，并使用我们的新方法从中获得相应的精确电子密度，我们通过计算偶极矩、核力、接触密度和其他基于密度的性质来证明这一点。

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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arXiv - PHYS - Chemical Physics

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