Tunable Optical Topological Transitions of Plasmon Polaritons in WTe Van Der Waals Films

Overview

Journal Light Sci Appl

Publisher Springer Nature

Date 2023 Aug 8

PMID 37553359

Authors

Yuangang Xie

Chong Wang

Fucong Fei

Yuqi Li

Qiaoxia Xing

Shenyang Huang

Yuchen Lei

Jiasheng Zhang

Lei Mu

Yaomin Dai

Fengqi Song

Hugen Yan

Affiliations

Soon will be listed here.

Abstract

Naturally existing in-plane hyperbolic polaritons and the associated optical topological transitions, which avoid the nano-structuring to achieve hyperbolicity, can outperform their counterparts in artificial metasurfaces. Such plasmon polaritons are rare, but experimentally revealed recently in WTe van der Waals thin films. Different from phonon polaritons, hyperbolic plasmon polaritons originate from the interplay of free carrier Drude response and interband transitions, which promise good intrinsic tunability. However, tunable in-plane hyperbolic plasmon polariton and its optical topological transition of the isofrequency contours to the elliptic topology in a natural material have not been realized. Here we demonstrate the tuning of the optical topological transition through Mo doping and temperature. The optical topological transition energy is tuned over a wide range, with frequencies ranging from 429 cm (23.3 microns) for pure WTe to 270 cm (37.0 microns) at the 50% Mo-doping level at 10 K. Moreover, the temperature-induced blueshift of the optical topological transition energy is also revealed, enabling active and reversible tuning. Surprisingly, the localized surface plasmon resonance in skew ribbons shows unusual polarization dependence, accurately manifesting its topology, which renders a reliable means to track the topology with far-field techniques. Our results open an avenue for reconfigurable photonic devices capable of plasmon polariton steering, such as canaling, focusing, and routing, and pave the way for low-symmetry plasmonic nanophotonics based on anisotropic natural materials.

Citing Articles

Steering and cloaking of hyperbolic polaritons at deep-subwavelength scales.

Teng H, Chen N, Hu H, de Abajo F, Dai Q Nat Commun. 2024; 15(1):4463.

PMID: 38796473 PMC: 11127984. DOI: 10.1038/s41467-024-48318-w.

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