横向量子流体中的超爬升模式：标志性统计和动力学特征

arXiv - PHYS - Other Condensed Matter Pub Date : 2024-04-04 DOI:arxiv-2404.03465

Chao Zhang, Massimo Boninsegni, Anatoly Kuklov, Nikolay Prokof'ev, Boris Svistunov

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引用次数: 0

摘要

超爬行模式是横向量子流体的标志性自由度，它描述了宽大的超流体一维界面和/或具有可忽略的 Peierls 势垒的边缘。我们报告了在简单晶格模型中，以及在吸附在石墨上的不完全固体单层$^4$He的自由边缘，由超爬行模式引起的量子形状波动的第一个直接数值证据。我们的数据明确揭示了超爬升模式的定义特征--边缘位移场与超流体相场的典型共轭--及其意想不到的含义，即超流体刚度可以从密度快照中推断出来。

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Superclimbing modes in transverse quantum fluids: signature statistical and dynamical features

Superclimbing modes are hallmark degrees of freedom of transverse quantum fluids describing wide superfluid one-dimensional interfaces and/or edges with negligible Peierls barrier. We report the first direct numeric evidence of quantum shape fluctuations -- caused by superclimbing modes -- in simple lattice models, as well as at the free edge of an incomplete solid monolayer of $^4$He adsorbed on graphite. Our data unambiguously reveals the defining feature of the superclimbing modes -- canonical conjugation of the edge displacement field to the field of superfluid phase -- and its unexpected implication, i.e., that superfluid stiffness can be inferred from density snapshots.

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arXiv - PHYS - Other Condensed Matter

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