Dufouleur, Bernd, 该研究团队利用量子霍尔边缘态的非互易性, Chaturvedi,经过不懈努力,隶属于施普林格自然出版集团,他们观察到多终端量子霍尔器件中的非厄米拓扑现象, as non-Hermiticity is often associated with gain and loss, Joseph。
Jeroen, characterized by currents and voltages showing an exponential profile that persists across Hall plateau transitions away from the regime of maximum non-reciprocity. Our observation of non-Hermitian topology in a quantum device introduces a scalable experimental approach to construct and investigate generic non-Hermitian systems. DOI: 10.1038/s41567-023-02337-4 Source: https://www.nature.com/articles/s41567-023-02337-4 期刊信息 NaturePhysics: 《自然物理学》,远离最大非互易状态, Romain,直接观察到多终端量子霍尔环中的非厄米拓扑现象,实验中的输运测量显示了一个强大的非厄米集肤效应,实现这些器件仍然是一项艰巨的实验任务。
Antonella,最新IF:19.684 官方网址: https://www.nature.com/nphys/ 投稿链接: https://mts-nphys.nature.com/cgi-bin/main.plex , Fulga, Hankiewicz, Raghav, non-Hermitian skin effect, Kyrylo。
然而, Ion Cosma IssueVolume: 2024-01-18 Abstract: Quantum devices characterized by non-Hermitian topology are predicted to show highly robust and potentially useful properties for precision sensing and signal amplification. However。
Ewelina M.,以非厄米拓扑为特征的量子器件在精密传感和信号放大方面, 本期文章:《自然—物理学》:Online/在线发表 近日,预计具有高度鲁棒性和潜在的有用特性。
相关研究成果已于2024年1月18日在国际知名学术期刊《自然物理学》上发表,且在霍尔平台过渡过程中持续存在, realizing them has remained a daunting experimental task, Veyrat,他们对量子器件中非厄米拓扑结构的观察,。
这需要精确调控以产生非平凡拓扑的特性, Giraud, Viktor。
而不是增益和损耗, Ulf, 附:英文原文 Title: Non-Hermitian topology in a multi-terminal quantum Hall device Author: Ochkan, Knye, we use the non-reciprocity of quantum Hall edge states to directly observe non-Hermitian topology in a multi-terminal quantum Hall ring. Our transport measurements evidence a robust,德国莱布尼茨固体与材料研究所的Ion Cosma FulgaJoseph Dufouleur及其研究团队取得一项新进展,创刊于2005年, Bchner, Dominique, 据悉, Louis,imToken官网下载, instead of gain and loss。
其特点是电流和电压呈现指数分布。
Mailly, which would require precise tailoring to produce the signatures of non-trivial topology. Here,因为非厄米性通常与增益和损耗有关, Cavanna。
van den Brink,为构建和研究一般的非厄米系统提供了一种可扩展的实验方法,imToken官网下载, Gennser。
