量子多体痕的高斯态近似

IF 4.6 2区 物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY SciPost Physics Pub Date : 2024-08-15 DOI:10.21468/scipostphys.17.2.055
Wouter Buijsman, Yevgeny Bar Lev
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引用次数: 0

摘要

量子多体疤痕是嵌入热特征状态海洋中的非典型、高度非热特征状态。这些特殊特征状态的特点是双向纠缠熵随子系统大小呈最对数扩展。我们使用数值优化技术来研究与实验相关的 PXP 模型的量子多体疤痕是否能被高斯态很好地近似。高斯态的参数数量与系统大小成二次方关系,因此比一般量子多体态的复杂度低得多,而一般量子多体态的参数数量与系统大小成指数关系。我们发现,虽然量子多体痕通常可以用(对称)高斯态很好地近似,但对于遍历(热)特征态却并非如此。这一观察结果表明,PXP 哈密顿的非遍历部分与某些二次母哈密顿有关,从而暗示了量子多体痕的起源。
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Gaussian state approximation of quantum many-body scars
Quantum many-body scars are atypical, highly nonthermal eigenstates embedded in a sea of thermal eigenstates that have been observed in, for example, kinetically constrained quantum many-body models. These special eigenstates are characterized by a bipartite entanglement entropy that scales as most logarithmically with the subsystem size. We use numerical optimization techniques to investigate if quantum many-body scars of the experimentally relevant PXP model can be well approximated by Gaussian states. Gaussian states are described by a number of parameters that scales quadratically with system size, thereby having a much lower complexity than generic quantum many-body states, for which this number scales exponentially. We find that while quantum many-body scars can typically be well approximated by (symmetrized) Gaussian states, this is not the case for ergodic (thermal) eigenstates. This observation suggests that the non-ergodic part of the PXP Hamiltonian is related to certain quadratic parent Hamiltonians, thereby hinting on the origin of the quantum many-body scars.
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来源期刊
SciPost Physics
SciPost Physics Physics and Astronomy-Physics and Astronomy (all)
CiteScore
8.20
自引率
12.70%
发文量
315
审稿时长
10 weeks
期刊介绍: SciPost Physics publishes breakthrough research articles in the whole field of Physics, covering Experimental, Theoretical and Computational approaches. Specialties covered by this Journal: - Atomic, Molecular and Optical Physics - Experiment - Atomic, Molecular and Optical Physics - Theory - Biophysics - Condensed Matter Physics - Experiment - Condensed Matter Physics - Theory - Condensed Matter Physics - Computational - Fluid Dynamics - Gravitation, Cosmology and Astroparticle Physics - High-Energy Physics - Experiment - High-Energy Physics - Theory - High-Energy Physics - Phenomenology - Mathematical Physics - Nuclear Physics - Experiment - Nuclear Physics - Theory - Quantum Physics - Statistical and Soft Matter Physics.
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