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Main Authors: Nie, Xinfang, Zhu, Xuanran, Fan, Yu-ang, Long, Xinyue, Liu, Hongfeng, Huang, Keyi, Xi, Cheng, Che, Liangyu, Zheng, Yuxuan, Feng, Yufang, Yang, Xiaodong, Lu, Dawei
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2410.07808
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author Nie, Xinfang
Zhu, Xuanran
Fan, Yu-ang
Long, Xinyue
Liu, Hongfeng
Huang, Keyi
Xi, Cheng
Che, Liangyu
Zheng, Yuxuan
Feng, Yufang
Yang, Xiaodong
Lu, Dawei
author_facet Nie, Xinfang
Zhu, Xuanran
Fan, Yu-ang
Long, Xinyue
Liu, Hongfeng
Huang, Keyi
Xi, Cheng
Che, Liangyu
Zheng, Yuxuan
Feng, Yufang
Yang, Xiaodong
Lu, Dawei
contents The accurate determination of the electronic structure of strongly correlated materials using first principle methods is of paramount importance in condensed matter physics, computational chemistry, and material science. However, due to the exponential scaling of computational resources, incorporating such materials into classical computation frameworks becomes prohibitively expensive. In 2016, Bauer et al. proposed a hybrid quantum-classical approach to correlated materials Phys. Rev. X 6, 031045 (2016)}] that can efficiently tackle the electronic structure of complex correlated materials. Here, we experimentally demonstrate that approach to tackle the computational challenges associated with strongly correlated materials. By seamlessly integrating quantum computation into classical computers, we address the most computationally demanding aspect of the calculation, namely the computation of the Green's function, using a spin quantum processor. Furthermore, we realize a self-consistent determination of the single impurity Anderson model through a feedback loop between quantum and classical computations. A quantum phase transition in the Hubbard model from the metallic phase to the Mott insulator is observed as the strength of electron correlation increases. As the number of qubits with high control fidelity continues to grow, our experimental findings pave the way for solving even more complex models, such as strongly correlated crystalline materials or intricate molecules.
format Preprint
id arxiv_https___arxiv_org_abs_2410_07808
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Self-Consistent Determination of Single-Impurity Anderson Model Using Hybrid Quantum-Classical Approach on a Spin Quantum Simulator
Nie, Xinfang
Zhu, Xuanran
Fan, Yu-ang
Long, Xinyue
Liu, Hongfeng
Huang, Keyi
Xi, Cheng
Che, Liangyu
Zheng, Yuxuan
Feng, Yufang
Yang, Xiaodong
Lu, Dawei
Quantum Physics
The accurate determination of the electronic structure of strongly correlated materials using first principle methods is of paramount importance in condensed matter physics, computational chemistry, and material science. However, due to the exponential scaling of computational resources, incorporating such materials into classical computation frameworks becomes prohibitively expensive. In 2016, Bauer et al. proposed a hybrid quantum-classical approach to correlated materials Phys. Rev. X 6, 031045 (2016)}] that can efficiently tackle the electronic structure of complex correlated materials. Here, we experimentally demonstrate that approach to tackle the computational challenges associated with strongly correlated materials. By seamlessly integrating quantum computation into classical computers, we address the most computationally demanding aspect of the calculation, namely the computation of the Green's function, using a spin quantum processor. Furthermore, we realize a self-consistent determination of the single impurity Anderson model through a feedback loop between quantum and classical computations. A quantum phase transition in the Hubbard model from the metallic phase to the Mott insulator is observed as the strength of electron correlation increases. As the number of qubits with high control fidelity continues to grow, our experimental findings pave the way for solving even more complex models, such as strongly correlated crystalline materials or intricate molecules.
title Self-Consistent Determination of Single-Impurity Anderson Model Using Hybrid Quantum-Classical Approach on a Spin Quantum Simulator
topic Quantum Physics
url https://arxiv.org/abs/2410.07808