Vaquero-Sabater Nonia, Carreras Abel, Orús Román, Mayhall Nicholas J, Casanova David
Donostia International Physics Center(DIPC), Donostia 20018, Euskadi, Spain.
Polimero eta Material Aurreratuak: Fisika, Kimika eta Teknologia Saila, Kimika Fakultatea, Euskal Herriko Unibertsitatea (UPV/EHU), PK 1072, Donostia 20080, Euskadi, Spain.
J Chem Theory Comput. 2024 Jun 25;20(12):5133-5144. doi: 10.1021/acs.jctc.4c00329. Epub 2024 Jun 9.
The adaptive derivative-assembled pseudo-Trotter variational quantum eigensolver (ADAPT-VQE) has emerged as a pivotal promising approach for electronic structure challenges in quantum chemistry with noisy quantum devices. Nevertheless, to surmount existing technological constraints, this study endeavors to enhance ADAPT-VQE's efficacy. Leveraging insights from the electronic structure theory, we concentrate on optimizing state preparation without added computational burden and guiding ansatz expansion to yield more concise wave functions with expedited convergence toward exact solutions. These advancements culminate in shallower circuits and, as demonstrated, reduced measurement requirements. This research delineates these enhancements and assesses their performance across mono, di, and tridimensional arrangements of H models, as well as in the water molecule. Ultimately, this work attests to the viability of physically motivated strategies in fortifying ADAPT-VQE's efficiency, marking a significant stride in quantum chemistry simulations.
自适应导数组装伪 Trotter 变分量子本征求解器(ADAPT-VQE)已成为一种关键的、有前景的方法,用于解决有噪声量子设备在量子化学中面临的电子结构挑战。然而,为了克服现有的技术限制,本研究致力于提高 ADAPT-VQE 的效率。利用电子结构理论的见解,我们专注于在不增加计算负担的情况下优化态制备,并指导量子态近似展开,以产生更简洁的波函数,更快地收敛到精确解。这些进展最终导致电路更浅,并且如所展示的那样,降低了测量要求。本研究描述了这些改进,并评估了它们在 H 模型的一维、二维和三维排列以及水分子中的性能。最终,这项工作证明了基于物理动机的策略在提高 ADAPT-VQE 效率方面的可行性,这标志着量子化学模拟取得了重大进展。
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