Non-Hermitian quantum fractals

被引：5

作者：

Sun, Junsong ^{[1
]}

Li, Chang-An ^{[2
]}

Guo, Qingyang ^{[1
]}

Zhang, Weixuan ^{[3
]}

Feng, Shiping ^{[4
]}

Zhang, Xiangdong ^{[3
]}

Guo, Huaiming ^{[1
]}

Trauzettel, Bjoern

机构：

[1] Beihang Univ, Sch Phys, Beijing 100191, Peoples R China

[2] Univ Wurzburg, Inst Theoret Phys & Astrophys, D-97074 Wurzburg, Germany

[3] Beijing Inst Technol, Sch Phys, Beijing Key Lab Nanophoton & Ultrafine Optoelectr, Key Lab Adv Optoelect Quantum Architecture & Meas, Beijing 100081, Peoples R China

[4] Beijing Normal Univ, Dept Phys, Beijing 100875, Peoples R China

来源：

PHYSICAL REVIEW B | 2024年 / 110卷 / 20期

关键词：

POWER; ELECTRONS;

D O I：

10.1103/PhysRevB.110.L201103

中图分类号：

T [工业技术];

学科分类号：

08 ;

摘要：

The first quantum fractal discovered in physics is the Hofstadter butterfly. It stems from large external magnetic fields. We discover instead a class of non-Hermitian quantum fractals (NHQFs) emerging in coupled Hatano-Nelson models on a tree lattice in the absence of any fields. Based on analytic solutions, we are able to rigorously identify the self-similar recursive structures in the energy spectrum and wave functions. We prove that the complex spectrum of NHQFs bears a resemblance to the Mandelbrot set in fractal theory. The self-similarity of NHQFs is rooted in the interplay between the iterative lattice configuration and non-Hermiticity. Moreover, we show that NHQFs exist in generalized non-Hermitian systems with iterative lattice structures. Our findings open another avenue for investigating quantum fractals in non-Hermitian systems.

引用

页数：6

共 50 条

[21] Non-Abelian generalization of non-Hermitian quasicrystals: PT-symmetry breaking, localization, entanglement, and topological transitions
Zhou, Longwen
[J]. PHYSICAL REVIEW B, 2023, 108 (01)
[22] Exact complex mobility edges and flagellate-like spectra for non-Hermitian quasicrystals with exponential hoppings
Wang, Li
Liu, Jiaqi
Wang, Zhenbo
Chen, Shu
[J]. PHYSICAL REVIEW B, 2024, 110 (14)
[23] Dissolution of the non-Hermitian skin effect in one-dimensional lattices with linearly varying nonreciprocal hopping
Hou, Bo
Xiao, Han
Lue, Rong
Zeng, Qi-Bo
[J]. PHYSICAL REVIEW B, 2024, 109 (09)
[24] Non-Hermitian gauged laser arrays with localized excitations: Anomalous threshold and generalized principle of selective pumping
Ge, Li
Gao, Zihe
Feng, Liang
[J]. PHYSICAL REVIEW B, 2023, 108 (10)
[25] From ergodicity to many-body localization in a one-dimensional interacting non-Hermitian Stark system
Liu, Jinghu
Xu, Zhihao
[J]. PHYSICAL REVIEW B, 2023, 108 (18)
[26] Multimode non-Hermitian framework for third harmonic generation in nonlinear photonic systems comprising two-dimensional materials
Christopoulos, Thomas
Kriezis, Emmanouil E.
Tsilipakos, Odysseas
[J]. PHYSICAL REVIEW B, 2023, 107 (03)
[27] Localization transitions and winding numbers for non-Hermitian Aubry-Andr?-Harper models with off-diagonal modulations
Cai, Xiaoming
[J]. PHYSICAL REVIEW B, 2022, 106 (21)
[28] Fate of Majorana zero modes, exact location of critical states, and unconventional real-complex transition in non-Hermitian quasiperiodic lattices
Tong Liu
Cheng, Shujie
Hao Guo
Gao Xianlong
[J]. PHYSICAL REVIEW B, 2021, 103 (10)
[29] Non-reciprocal population dynamics in a quantum trimer
Downing, C. A.
Zueco, D.
[J]. PROCEEDINGS OF THE ROYAL SOCIETY A-MATHEMATICAL PHYSICAL AND ENGINEERING SCIENCES, 2021, 477 (2255):
[30] Discriminating quantum field theories in non-inertial frames
Doukas, Jason
Adesso, Gerardo
Pirandola, Stefano
Dragan, Andrzej
[J]. CLASSICAL AND QUANTUM GRAVITY, 2015, 32 (03)

← 1 2 3 4 5 →