Quantum valley Hall effect and perfect valley filter based on photonic analogs of transitional metal dichalcogenides

The valley degree of freedom of electrons in two-dimensional transition metal dichalcogenides has been extensively studied by theory (1–4), optical (5–9), and optoelectronic (10–13) experiments. However, generation and detection of pure valley current without relying on optical selection have not yet been demonstrated in these materials. Here, we report that valley current can be electrically induced and detected through the valley Hall effect and inverse valley Hall effect, respectively, in monolayer molybdenum disulfide. We compare temperature and channel length dependence of nonlocal electrical signals in monolayer and multilayer samples to distinguish the valley Hall effect from classical ohmic contributions. Notably, valley transport is observed over a distance of 4 μm in monolayer samples at room temperature. Our findings will enable a new generation of electronic devices using the valley degree of freedom, which can be used for future novel valleytronic applications.

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Ultrafast non-excitonic valley Hall effect in MoS2/WTe2 heterobilayers

Nature Communications ◽

10.1038/s41467-021-21013-w ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Jekwan Lee ◽

Wonhyeok Heo ◽

Myungjun Cha ◽

Kenji Watanabe ◽

Takashi Taniguchi ◽

...

Keyword(s):

Hall Effect ◽

Quantitative Information ◽

Exciton Energy ◽

Electron Hole ◽

Kerr Rotation ◽

Polarized Electrons ◽

Spatially Resolved ◽

Long Valley ◽

Bound Electron ◽

Valley Hall Effect

AbstractThe valley Hall effect (VHE) in two-dimensional (2D) van der Waals (vdW) crystals is a promising approach to study the valley pseudospin. Most experiments so far have used bound electron-hole pairs (excitons) through local photoexcitation. However, the valley depolarization of such excitons is fast, so that several challenges remain to be resolved. We address this issue by exploiting a unipolar VHE using a heterobilayer made of monolayer MoS2/WTe2 to exhibit a long valley-polarized lifetime due to the absence of electron-hole exchange interaction. The unipolar VHE is manifested by reduced photoluminescence at the MoS2 A exciton energy. Furthermore, we provide quantitative information on the time-dependent valley Hall dynamics by performing the spatially-resolved ultrafast Kerr-rotation microscopy; we find that the valley-polarized electrons persist for more than 4 nanoseconds and the valley Hall mobility exceeds 4.49 × 103 cm2/Vs, which is orders of magnitude larger than previous reports.

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Fine structures of valley-polarized excitonic states in monolayer transitional metal dichalcogenides

Nanophotonics ◽

10.1515/nanoph-2020-0054 ◽

2020 ◽

Vol 9 (7) ◽

pp. 1811-1829 ◽

Cited By ~ 1

Author(s):

Zhipeng Li ◽

Tianmeng Wang ◽

Shengnan Miao ◽

Zhen Lian ◽

Su-Fei Shi

Keyword(s):

Optical Excitation ◽

Coherence Time ◽

Two Dimensions ◽

Degree Of Freedom ◽

Research Progress ◽

Many Body ◽

Transitional Metal ◽

Metal Dichalcogenides ◽

Fine Structures ◽

Excitonic States

AbstractMonolayer transitional metal dichalcogenides (TMDCs), a new class of atomically thin semiconductor, respond to optical excitation strongly with robust excitons, which stem from the reduced screening in two dimensions. These excitons also possess a new quantum degree of freedom known as valley spin, which has inspired the field of valleytronics. The strongly enhanced Coulomb interaction allows the exciton to bind with other particles to form new excitonic states. However, despite the discovery of trions, most of the excitonic states in monolayer TMDCs remain elusive until recently, when new light was shed into the fascinating excitonic fine structures with drastically improved sample quality through boron nitride encapsulation. Here, we review the latest research progress on fine structures of excitonic states in monolayer TMDCs, with a focus on tungsten-based TMDCs and related alloy. Many of the new excitonic complexes inherit the valley degree of freedom, and the valley-polarized dark excitonic states are of particular interest because of their long lifetime and possible long valley coherence time. The capability of resolving the excitonic fine structures also enables the investigation of exciton–phonon interactions. The knowledge of the interlayer between excitons and other particles not only advances our understanding of many-body effects in the monolayer TMDCs but also provides guidance on future applications based on TMDCs.

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