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Trapped Ion Quantum Computing Superconducting Qubits Quantum Simulation

Electronic Band Structure of Silicon Determined via a Variational Adiabatic Eigensolver: Theory and Experiment

arXiv
Authors: Xingrui Liu, Liyang Sui, Tianqi Cai, Zhiwen Zong, Kunliang Bu, Wenyan Jin, Bowen Chen, Xutao Zhang, Yufan Li, Zhihao Gong, Yicong Zheng, Shengyu Zhang, Jianlan Wu, Yi Yin

Year

2026

Paper ID

69513

Status

Preprint

Abstract Read

~2 min

Abstract Words

170

Citations

N/A

Abstract

This work addresses the critical challenge of excited-state preparation for semiconductor band structure calculations. We introduce a variational adiabatic eigensolver (VAE) protocol that combines adiabatic evolution with variational optimization to prepare high-fidelity eigenstates on noisy intermediate-scale quantum (NISQ) devices. Applying a momentum-space truncation, we accurately compute the electronic band structure of silicon - an idealized infinite periodic system - using only a modest number of qubits. Our approach employs multi-qubit parameterized circuits and a phase-based loss function, overcoming limitations of conventional methods. These limitations include the circuit-construction difficulty in traditional adiabatic approaches and the reduced accuracy of variational quantum eigensolvers for excited states. Through rigorous numerical simulation and experimental implementation on a superconducting quantum processor, we successfully prepare silicon's valence-band and conduction-band eigenstates. Single-shot readout yields state fidelities exceeding 96%, and the measured energy expectations agree with theoretical band energies within 0.5 eV. Further refinement via single-frequency oscillation fitting reduces the energy deviation to below 0.01 eV. This framework provides a robust and practical pathway for precisely determining electronic structures in quantum materials.

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  • This paper contributes to the Quantum Simulation research area in the Quantum Articles archive.
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  • This work addresses the critical challenge of excited-state preparation for semiconductor band structure calculations.

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