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Variational Quantum Computation of Molecular Linear Response Properties on a Superconducting Quantum Processor.

Kaixuan Huang, Xiaoxia Cai, Hao Li, Zi-Yong Ge, Ru-Chuen Hou, Hekang Li, Tong Liu, Yun-hao Shi, Chi-Tong Chen, D. Zheng, Kai Xu, Zhi-Bo Liu, Zhendong Li, Heng Fan, W. Fang·January 7, 2022·DOI: 10.1021/acs.jpclett.2c02381
MedicinePhysics

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Abstract

Simulating response properties of molecules is crucial for interpreting experimental spectroscopies and accelerating materials design. However, it remains a long-standing computational challenge for electronic structure methods on classical computers. While quantum computers hold the promise of solving this problem more efficiently in the long run, existing quantum algorithms requiring deep quantum circuits are infeasible for near-term noisy quantum processors. Herein, we introduce a pragmatic variational quantum response (VQR) algorithm for response properties, which circumvents the need for deep quantum circuits. Using this algorithm, we report the first simulation of linear response properties of molecules including dynamic polarizabilities and absorption spectra on a superconducting quantum processor. Our results indicate that a large class of important dynamical properties, such as Green's functions, are within the reach of near-term quantum hardware using this algorithm in combination with suitable error mitigation techniques.

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