He-Liang Huang
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Explore the profile of He-Liang Huang including associated specialties, affiliations and a list of published articles.
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21
Citations
186
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Recent Articles
1.
Ding C, Lobo E, Alimuddin M, Xu X, Zhang S, Banik M, et al.
Phys Rev Lett
. 2024 Dec;
133(20):200201.
PMID: 39626717
We implement an experiment on a photonic quantum processor establishing efficacy of the elementary quantum system in classical information storage. The advantage is established by considering a class of simple...
2.
Ye Y, He T, Huang H, Wei Z, Zhang Y, Zhao Y, et al.
Phys Rev Lett
. 2023 Dec;
131(21):210603.
PMID: 38072603
Fault-tolerant quantum computing based on surface code has emerged as an attractive candidate for practical large-scale quantum computers to achieve robust noise resistance. To achieve universality, magic states preparation is...
3.
Cao S, Wu B, Chen F, Gong M, Wu Y, Ye Y, et al.
Nature
. 2023 Jul;
619(7971):738-742.
PMID: 37438533
Scalable generation of genuine multipartite entanglement with an increasing number of qubits is important for both fundamental interest and practical use in quantum-information technologies. On the one hand, multipartite entanglement...
4.
Gong M, Huang H, Wang S, Guo C, Li S, Wu Y, et al.
Sci Bull (Beijing)
. 2023 Apr;
68(9):906-912.
PMID: 37085397
Classifying many-body quantum states with distinct properties and phases of matter is one of the most fundamental tasks in quantum many-body physics. However, due to the exponential complexity that emerges...
5.
Ying C, Cheng B, Zhao Y, Huang H, Zhang Y, Gong M, et al.
Phys Rev Lett
. 2023 Mar;
130(11):110601.
PMID: 37001092
Although near-term quantum computing devices are still limited by the quantity and quality of qubits in the so-called NISQ era, quantum computational advantage has been experimentally demonstrated. Moreover, hybrid architectures...
6.
Luo Y, Su H, Huang H, Wang X, Yang T, Li L, et al.
Sci Bull (Beijing)
. 2023 Jan;
63(24):1611-1615.
PMID: 36658852
Since the pillars of quantum theory were established, it was already noted that quantum physics may allow certain correlations defying any local realistic picture of nature, as first recognized by...
7.
Zhu Q, Cao S, Chen F, Chen M, Chen X, Chung T, et al.
Sci Bull (Beijing)
. 2022 Dec;
67(3):240-245.
PMID: 36546072
To ensure a long-term quantum computational advantage, the quantum hardware should be upgraded to withstand the competition of continuously improved classical algorithms and hardwares. Here, we demonstrate a superconducting quantum...
8.
Zhao Y, Ye Y, Huang H, Zhang Y, Wu D, Guan H, et al.
Phys Rev Lett
. 2022 Jul;
129(3):030501.
PMID: 35905349
Quantum error correction is a critical technique for transitioning from noisy intermediate-scale quantum devices to fully fledged quantum computers. The surface code, which has a high threshold error rate, is...
9.
Zhu Q, Sun Z, Gong M, Chen F, Zhang Y, Wu Y, et al.
Phys Rev Lett
. 2022 May;
128(16):160502.
PMID: 35522497
Understanding various phenomena in nonequilibrium dynamics of closed quantum many-body systems, such as quantum thermalization, information scrambling, and nonergodic dynamics, is crucial for modern physics. Using a ladder-type superconducting quantum...
10.
Wu Y, Bao W, Cao S, Chen F, Chen M, Chen X, et al.
Phys Rev Lett
. 2021 Nov;
127(18):180501.
PMID: 34767433
Scaling up to a large number of qubits with high-precision control is essential in the demonstrations of quantum computational advantage to exponentially outpace the classical hardware and algorithmic improvements. Here,...