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1. Observation of topologically protected states at crystalline phase boundaries in single-layer WSe2

   https://doi.org/10.1038/s41467-018-05672-w  

   Ugeda, Miguel M. ; Pulkin, Artem ; Tang, Shujie ; Ryu, Hyejin ; Wu, Quansheng ; Zhang, Yi ; Wong, Dillon ; Pedramrazi, Zahra ; Martín-Recio, Ana ; Chen, Yi ; et al ( August 2018 , Nature Communications)

   Transition metal dichalcogenide materials are unique in the wide variety of structural and electronic phases they exhibit in the two-dimensional limit. Here we show how such polymorphic flexibility can be used to achieve topological states at highly ordered phase boundaries in a new quantum spin Hall insulator (QSHI), 1T′-WSe₂. We observe edge states at the crystallographically aligned interface between a quantum spin Hall insulating domain of 1T′-WSe₂and a semiconducting domain of 1H-WSe₂in contiguous single layers. The QSHI nature of single-layer 1T′-WSe₂is verified using angle-resolved photoemission spectroscopy to determine band inversion around a 120 meV energy gap, as well as scanning tunneling spectroscopy to directly image edge-state formation. Using this edge-state geometry we confirm the predicted penetration depth of one-dimensional interface states into the two-dimensional bulk of a QSHI for a well-specified crystallographic direction. These interfaces create opportunities for testing predictions of the microscopic behavior of topologically protected boundary states.

    

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2. Metal‐Guided Selective Growth of 2D Materials: Demonstration of a Bottom‐Up CMOS Inverter

   https://doi.org/10.1002/adma.201900861  

   Chiu, Ming‐Hui ; Tang, Hao‐Ling ; Tseng, Chien‐Chih ; Han, Yimo ; Aljarb, Areej ; Huang, Jing‐Kai ; Wan, Yi ; Fu, Jui‐Han ; Zhang, Xixiang ; Chang, Wen‐Hao ; et al ( March 2019 , Advanced Materials)

   2D transition metal dichalcogenide (TMD) layered materials are promising for future electronic and optoelectronic applications. The realization of large‐area electronics and circuits strongly relies on wafer‐scale, selective growth of quality 2D TMDs. Here, a scalable method, namely, metal‐guided selective growth (MGSG), is reported. The success of control over the transition‐metal‐precursor vapor pressure, the first concurrent growth of two dissimilar monolayer TMDs, is demonstrated in conjunction with lateral or vertical TMD heterojunctions at precisely desired locations over the entire wafer in a single chemical vapor deposition (VCD) process. Owing to the location selectivity, MGSG allows the growth of p‐ and n‐type TMDs with spatial homogeneity and uniform electrical performance for circuit applications. As a demonstration, the first bottom‐up complementary metal‐oxide‐semiconductor inverter based on p‐type WSe₂and n‐type MoSe₂is achieved, which exhibits a high and reproducible voltage gain of 23 with little dependence on position.

    

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3. Layer‐Number‐Dependent Electronic and Optoelectronic Properties of 2D WSe 2 ‐Organic Hybrid Heterojunction

   https://doi.org/10.1002/admi.201900637  

   Ji, Jaehoon ; Choi, Jong Hyun ( July 2019 , Advanced Materials Interfaces)

   One of the most attractive features of 2D WSe₂is a tunability in its electronic and optoelectronic properties depending on the layer number. To harness such unique characteristics for device applications, high quality and easily processable heterojunctions are required and relevant layer‐number‐dependent properties must be understood. Herein, a study is reported on hybrid heterojunctions between 2D WSe₂and organic molecules from one‐step solution chemistry and their layer‐number‐dependent properties. Eosin Y (EY) dye is selected as a p‐dopant and uniformly stacked on mechanically exfoliated WSe₂flakes via van der Waals interaction, forming a hybrid heterojunction with a type II alignment. The EY‐WSe₂heterojunction shows significantly enhanced currents compared to pristine WSe₂with a lower barrier height and a longer effective screening length. The work function of the heterostructure is also lower than that of pristine WSe₂. The efficient exciton dissociation and doping effect by EY are confirmed by photocurrent and photoluminescence measurements, where WSe₂emission is markedly quenched by EY and exciton contribution decreases with layer number. These findings shed critical insights into layer‐number‐dependent electronic and optoelectronic properties of organic‐WSe₂layers and also provide simple yet effective means to construct transition metal dichalcogenide‐based heterostructures, which should be valuable for developing layered 2D devices.

    

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4. Structural parameters of hyperbolic metamaterials controlling high-k mode resonant wavelengths

   https://doi.org/10.1364/JOSAB.404763  

   Sohr, Patrick ; Law, Stephanie ( November 2020 , Journal of the Optical Society of America B)

   Layered semiconductor hyperbolic metamaterials (HMMs) are composite materials composed of alternating subwavelength-doped (metal) and undoped (dielectric) semiconductor layers. These materials support the propagation of light with large wave vectors through modes called volume plasmon polaritons (VPPs). In this paper, we use finite-element modeling and effective medium analysis (EMA) to investigate how the number of periods, the period thickness, and the overall HMM thickness affect the VPP mode-resonant wavelengths. We show that the overall HMM thickness has a larger impact on shifting the resonant wavelengths of the VPP modes than the subwavelength structure. We also show that the main limitation of EMA for this application is an inability to account for the boundary conditions at the substrate.

    

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5. Probing Dopant Redistribution, Phase Propagation, and Local Chemical Changes in the Synthesis of Layered Oxide Battery Cathodes

   https://doi.org/10.1002/aenm.202002719  

   Yang, Zhijie ; Mu, Linqin ; Hou, Dong ; Rahman, Muhammad Mominur ; Xu, Zhengrui ; Liu, Jue ; Nordlund, Dennis ; Sun, Cheng‐Jun ; Xiao, Xianghui ; Lin, Feng ( November 2020 , Advanced Energy Materials)

   Achieving the targeted control of layered oxide properties calls for more fundamental studies to mechanistically probe their evolution during their synthesis. Herein, dopant distribution, phase propagation, and local chemical changes as well as their interplay in multielement‐doped LiNiO₂materials are investigated using spectroscopic, imaging, and scattering techniques. It is shown that dopants undergo dynamic redistribution in the Ni(OH)₂host lattice at the early stage of calcination (below 300 °C). Such redistribution behavior exhibits strong dopant‐dependent characteristics, allowing for targeted surface and bulk doping control. The Ni oxidation process exhibits depth‐dependent characteristics and the most rapid Ni oxidation takes place between 300 and 700 °C. Using Ni oxidation state as the proxy for the phase transformation, the buildup of heterogenous phase propagation in the early stage of calcination is shown, especially along the radial direction of secondary particles. The radial heterogenous phase distribution gradually decreases upon completing the calcination. However, a high degree of mosaic‐like heterogeneity may still be present in the final product, departing from the perfect layered oxide. The present study offers fundamental insights into manipulating multiscale materials properties during calcination for obtaining stable, high‐energy layered oxide cathodes.

    

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