Periodic plane-wave electronic structure calculations on quantum computers

Duo Song, Nicholas P. Bauman, Guen Prawiroatmodjo, Bo Peng, Cassandra Granade, Kevin M. Rosso, Guang Hao Low, Martin Roetteler, Karol Kowalski, Eric J. Bylaska
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引用次数: 2

Abstract

A procedure for defining virtual spaces, and the periodic one-electron and two-electron integrals, for plane-wave second quantized Hamiltonians has been developed, and it was validated using full configuration interaction (FCI) calculations, as well as executions of variational quantum eigensolver (VQE) circuits on Quantinuum’s ion trap quantum computers accessed through Microsoft’s Azure Quantum service. This work is an extension to periodic systems of a new class of algorithms in which the virtual spaces were generated by optimizing orbitals from small pairwise CI Hamiltonians, which we term as correlation optimized virtual orbitals with the abbreviation COVOs. In this extension, the integration of the first Brillouin zone is automatically incorporated into the two-electron integrals. With these procedures, we have been able to derive virtual spaces, containing only a few orbitals, that were able to capture a significant amount of correlation. The focus in this manuscript is on comparing the simulations of small molecules calculated with plane-wave basis sets with large periodic unit cells at the \(\Gamma\)-point, including images, to results for plane-wave basis sets with aperiodic unit cells. The results for this approach were promising, as we were able to obtain good agreement between periodic and aperiodic results for an LiH molecule. Calculations performed on the Quantinuum H1-1 quantum computer produced surprisingly good energies, in which the error mitigation played a small role in the quantum hardware calculations and the (noisy) quantum simulator results. Using a modest number of circuit runs (500 shots), we reproduced the FCI values for the 1 COVO Hamiltonian with an error of 11 milliHartree, which is expected to improve with a larger number of circuit runs.

基于量子计算机的周期性平面波电子结构计算
为平面波第二量子化哈密顿量定义虚拟空间和周期单电子和双电子积分的程序已经开发出来,并使用全组态相互作用(FCI)计算以及在量子离子阱量子计算机上执行变分量子特征解算器(VQE)电路进行了验证,这些计算机通过微软的Azure量子服务访问。本文是对一类新的周期系统算法的扩展,其中虚拟空间是通过从小的成对CI哈密顿量优化轨道生成的,我们将其称为相关优化虚拟轨道,缩写为COVOs。在此扩展中,第一布里渊区的积分自动纳入双电子积分。通过这些程序,我们已经能够推导出只包含少数轨道的虚拟空间,这些空间能够捕捉到大量的相关性。本文的重点是比较在\(\Gamma\) -点用平面波基集与大周期单元格计算的小分子的模拟,包括图像,与非周期单元格平面波基集的结果。这种方法的结果是有希望的,因为我们能够在LiH分子的周期和非周期结果之间获得很好的一致性。在量子H1-1量子计算机上进行的计算产生了令人惊讶的良好能量,其中误差缓解在量子硬件计算和(有噪声的)量子模拟器结果中发挥了很小的作用。使用少量的电路运行(500次射击),我们以11毫哈特里的误差再现了1 COVO哈密顿量的FCI值,预计随着电路运行次数的增加,FCI值将得到改善。
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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期刊介绍: Journal of Materials Science: Materials Theory publishes all areas of theoretical materials science and related computational methods. The scope covers mechanical, physical and chemical problems in metals and alloys, ceramics, polymers, functional and biological materials at all scales and addresses the structure, synthesis and properties of materials. Proposing novel theoretical concepts, models, and/or mathematical and computational formalisms to advance state-of-the-art technology is critical for submission to the Journal of Materials Science: Materials Theory. The journal highly encourages contributions focusing on data-driven research, materials informatics, and the integration of theory and data analysis as new ways to predict, design, and conceptualize materials behavior.
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