Your search keyword '"Zhang, Jingning"' showing total 6 results

1. Observing frustrated quantum magnetism in two-dimensional ion crystals

Author

Qiao, Mu, Cai, Zhengyang, Wang, Ye, Du, Botao, Jin, Naijun, Chen, Wentao, Wang, Pengfei, Luan, Chunyang, Gao, Erfu, Sun, Ximo, Tian, Haonan, Zhang, Jingning, and Kim, Kihwan

Subjects

Condensed Matter - Other Condensed Matter, Quantum Physics, Condensed Matter - Materials Science, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, Quantum Physics (quant-ph), Other Condensed Matter (cond-mat.other)

Abstract

Two-dimensional (2D) quantum magnetism is a paradigm in strongly correlated many-body physics. The understanding of 2D quantum magnetism can be expedited by employing a controllable quantum simulator that faithfully maps 2D-spin Hamiltonians. The 2D quantum simulators can exhibit exotic phenomena such as frustrated quantum magnetism and topological order and can be used to show quantum computational advantages. Many experimental platforms are being developed, including Rydberg atoms and superconducting annealers. However, with trapped-ion systems, which showed the most advanced controllability and quantum coherence, quantum magnetism was explored in one-dimensional chains. Here, we report simulations of frustrated quantum magnetism with 2D ion crystals. We create a variety of spin-spin interactions for quantum magnets, including those that exhibit frustration by driving different vibrational modes and adiabatically prepare the corresponding ground states. The experimentally measured ground states are consistent with the theoretical predictions and are highly degenerate for geometrically frustrated spin models in two dimensions. Quantum coherence of the ground states is probed by reversing the time evolution of the B-field to the initial value and then measuring the extent to which the remaining state coincides with the initial state. Our results open the door for quantum simulations with 2D ion crystals., 11 pages, 9 figures

Published

2022

2. Quantum circuit architecture search on a superconducting processor

Author

Linghu, Kehuan, Qian, Yang, Wang, Ruixia, Hu, Meng-Jun, Li, Zhiyuan, Li, Xuegang, Xu, Huikai, Zhang, Jingning, Ma, Teng, Zhao, Peng, Liu, Dong E., Hsieh, Min-Hsiu, Wu, Xingyao, Du, Yuxuan, Tao, Dacheng, Jin, Yirong, and Yu, Haifeng

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

Variational quantum algorithms (VQAs) have shown strong evidences to gain provable computational advantages for diverse fields such as finance, machine learning, and chemistry. However, the heuristic ansatz exploited in modern VQAs is incapable of balancing the tradeoff between expressivity and trainability, which may lead to the degraded performance when executed on the noisy intermediate-scale quantum (NISQ) machines. To address this issue, here we demonstrate the first proof-of-principle experiment of applying an efficient automatic ansatz design technique, i.e., quantum architecture search (QAS), to enhance VQAs on an 8-qubit superconducting quantum processor. In particular, we apply QAS to tailor the hardware-efficient ansatz towards classification tasks. Compared with the heuristic ansatze, the ansatz designed by QAS improves test accuracy from 31% to 98%. We further explain this superior performance by visualizing the loss landscape and analyzing effective parameters of all ansatze. Our work provides concrete guidance for developing variable ansatze to tackle various large-scale quantum learning problems with advantages.

Published

2022

3. Realizing discrete time crystal in an one-dimensional superconducting qubit chain

Author

Xu, Huikai, Zhang, Jingning, Han, Jiaxiu, Li, Zhiyuan, Xue, Guangming, Liu, Weiyang, Jin, Yirong, and Yu, Haifeng

Subjects

Quantum Physics, FOS: Physical sciences, Disordered Systems and Neural Networks (cond-mat.dis-nn), Condensed Matter - Disordered Systems and Neural Networks, Quantum Physics (quant-ph)

Abstract

Floquet engineering, i.e. driving the system with periodic Hamiltonians, not only provides great flexibility in analog quantum simulation, but also supports phase structures of great richness. It has been proposed that Floquet systems can support a discrete time-translation symmetry (TTS) broken phase, dubbed the discrete time crystal (DTC). This proposal, as well as the exotic phase, has attracted tremendous interest among the community of quantum simulation. Here we report the observation of the DTC in an one-dimensional superconducting qubit chain. We experimentally realize long-time stroboscopic quantum dynamics of a periodically driven spin system consisting of 8 transmon qubits, and obtain a lifetime of the DTC order limited by the coherence time of the underlying physical platform. We also explore the crossover between the discrete TTS broken and unbroken phases via various physical signatures. Our work extends the usage of superconducting circuit systems in quantum simulation of many-body physics, and provides an experimental tool for investigating non-equilibrium dynamics and phase structures.

Published

2021

4. Transmon qubit with relaxation time exceeding 0.5 milliseconds

Author

Wang, Chenlu, Li, Xuegang, Xu, Huikai, Li, Zhiyuan, Wang, Junhua, Yang, Zhen, Mi, Zhenyu, Liang, Xuehui, Su, Tang, Yang, Chuhong, Wang, Guangyue, Wang, Wenyan, Li, Yongchao, Chen, Mo, Li, Chengyao, Linghu, Kehuan, Han, Jiaxiu, Zhang, Yingshan, Feng, Yulong, Song, Yu, Ma, Teng, Zhang, Jingning, Wang, Ruixia, Zhao, Peng, Liu, Weiyang, Xue, Guangming, Jin, Yirong, and Yu, Haifeng

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

By using the dry etching process of tantalum (Ta) film, we had obtained transmon qubit with the best lifetime (T1) 503 us, suggesting that the dry etching process can be adopted in the following multi-qubit fabrication with Ta film. We also compared the relaxation and coherence times of transmons made with different materials (Ta, Nb and Al) with the same design and fabrication processes of Josephson junction, we found that samples prepared with Ta film had the best performance, followed by those with Al film and Nb film. We inferred that the reason for this difference was due to the different loss of oxide materials located at the metal-air interface.

Published

2021

5. Single ion-qubit exceeding one hour coherence time

Author

Wang, Pengfei, Luan, Chun-Yang, Qiao, Mu, Um, Mark, Zhang, Junhua, Wang, Ye, Yuan, Xiao, Gu, Mile, Zhang, Jingning, and Kim, Kihwan

Subjects

Quantum Physics, Hardware_MEMORYSTRUCTURES, ComputerSystemsOrganization_MISCELLANEOUS, FOS: Physical sciences, TheoryofComputation_GENERAL, Quantum Physics (quant-ph)

Abstract

Realizing a long coherence time quantum memory is a major challenge of current quantum technology. Here, we report a single \Yb ion-qubit memory with over one hour coherence time, an order of improvement compared to the state-of-the-art record. The long coherence time memory is realized by addressing various technical challenges such as ambient magnetic-field noise, phase noise and leakage of the microwave oscillator. Moreover, systematically study the decoherence process of our quantum memory by quantum process tomography, which enables to apply the strict criteria of quantum coherence, relative entropy of coherence. We also benchmark our quantum memory by its ability in preserving quantum information, i.e., the robustness of quantum memory, which clearly shows that over 6000 s, our quantum memory preserves non-classical quantum information. Our results verify the stability of the quantum memory in hours level and indicate its versatile applicability in various scenarios., 7 pages, 7 figures

Published

2020

6. Characterize noise correlation and enhance coherence via qubit motion

Author

Han, Jiaxiu, Li, Zhiyuan, Zhang, Jingning, Xu, Huikai, Linghu, Kehuan, Li, Yongchao, Li, Chengyao, Chen, Mo, Yang, Zhen, Wang, Junhua, Ma, Teng, Xue, Guangming, Jin, Yirong, and Yu, Haifeng

Subjects

Quantum Physics, Computer Science::Emerging Technologies, FOS: Physical sciences, Hardware_ARITHMETICANDLOGICSTRUCTURES, Quantum Physics (quant-ph)

Abstract

The identification of spacial noise correlation is of critical importance in developing error-corrected quantum devices, but it has barely been studied so far. In this work, we utilize an effective new method called qubit motion, to efficiently determine the noise correlations between any pair of qubits in a 7-qubit superconducting quantum system. The noise correlations between the same pairs of qubits are also investigated when the qubits are at distinct operating frequencies. What's more, in this multi-qubit system with the presence of noise correlations, we demonstrate the enhancing effect of qubit motion on the coherence of logic qubit, and we propose a Motion-CPMG operation sequence to more efficiently protect the logic state from decoherence, which is experimentally demonstrated to extend the decoherence time of logic qubit by nearly one order of magnitude.

Published

2020