Related papers: Remote entanglement generation via enhanced quantum state transfer

Remote entanglement generation via enhanced quantum state transfer

URL: http://arxiv.org/abs/2506.06669v1
Date: Sat, 07 Jun 2025 05:24:16 GMT
Title: Remote entanglement generation via enhanced quantum state transfer
Authors: Tian-Le Wang, Peng Wang, Ze-An Zhao, Sheng Zhang, Ren-Ze Zhao, Xiao-Yan Yang, Hai-Feng Zhang, Zhi-Fei Li, Yuan Wu, Liang-Liang Guo, Yong Chen, Hao-Ran Tao, Lei Du, Chi Zhang, Zhi-Long Jia, Wei-Cheng Kong, Peng Duan, Ming Gong, Guo-Ping Guo,
Abstract summary: We propose a new quantum state transfer scheme based on a zig-zag configuration.<n>We show that this new parameter can suppress the population in the intermediate qubits, thereby reducing losses.<n>Results highlight the potential of our enhanced quantum state transfer scheme for scalable and noise-resilient quantum communication and computing.
Score: 24.749735285149274
License: http://creativecommons.org/licenses/by-sa/4.0/
Abstract: Achieving robust and scalable remote quantum entanglement is a fundamental challenge for the development of distributed quantum networks and modular quantum computing systems. Along this, perfect state transfer (PST) and fractional state transfer (FST) have emerged as promising schemes for quantum state transfer and remote entanglement generation using only nearest-neighbor couplings. However, the current implementations suffer from quantum loss and limited parameter tunability. In this work, we propose a new quantum state transfer scheme based on a zig-zag configuration, which introduces a controlling parameter for PST and FST. We show that this new parameter can suppress the population in the intermediate qubits, thereby reducing losses. We experimentally demonstrate the dynamics of different configurations on a superconducting quantum processor, achieving an $18\%$ reduction in error for remote Bell state generation in a 1D ($1\times5$) qubit chain, and exhibit robustness against certain types of noise. Then we extend our approach to a 2D network, successfully generating a W state among the four corner qubits. These results highlight the potential of our enhanced quantum state transfer scheme for scalable and noise-resilient quantum communication and computing.

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