Vertical Heterostructure of SnS–MoS<sub>2</sub> Synthesized by Sulfur-Preloaded Chemical Vapor Deposition

Diao, Mengjuan; Li, Hui; Hou, Ruipeng; Liang, Ying; Wang, Jun; Luo, Zhishan; Huang, Zhipeng; Zhang, Chi

doi:10.1021/acsami.9b19495

Cited by 24 publications

(24 citation statements)

References 62 publications

(123 reference statements)

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“…[4,8,10] Gong et al achieved direct growth of MoS 2 /WS 2 heterostructures on SiO 2 / Si substrate by CVD. [11] Several other TMDs vdWHs, such as MoS 2 /CdS, [12] WS 2 /NbSe 2 , [13] SnS/MoS 2 , [14] have been successfully synthesized by the CVD method. [15,16] The growth of vertical vdWHs is more difficult than that of bilayer TMDs.…”

Section: Introductionmentioning

confidence: 99%

Controllable Epitaxial Growth of Large‐Area MoS₂/WS₂ Vertical Heterostructures by Confined‐Space Chemical Vapor Deposition

Zhang

Huangfu

et al. 2021

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The controllable large‐area growth of single‐crystal vertical heterostructures based on 2D transition metal dichalcogenides (TMDs) remains a challenge. Here, large‐area vertical MoS2/WS2 heterostructures are synthesized using single‐step confined‐space chemical vapor epitaxy. The heterostructures can evolve into two different kinds by switching the H2 flow on and off: MoS2/WS2 heterostructures with multiple WS2 domains can be achieved without introducing the H2 flow due to the numerous nucleation centers on the bottom MoS2 monolayer during the transition stage between the MoS2 and WS2 monolayer growth. In contrast, isolated MoS2/WS2 heterostructures with single WS2 domain can be obtained with introducing the H2 flow due to the reduced nucleation centers on the bottom MoS2 monolayer arising from the hydrogen etching effect. Both the two kinds of the vertical MoS2/WS2 heterostructures feature high quality. The photodetectors based on the isolated MoS2/WS2 heterostructures exhibit a high responsivity of 68 mA W−1 and a short response time of 35 ms. This single‐step chemical vapor epitaxy can be used to synthesize vertical MoS2/WS2 heterostructures with high production efficiency. The new epitaxial growth approach may open new pathways to fabricate large‐area heterostructures made of different 2D TMDs monolayers of interest to electronics, optoelectronics, and other applications.

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Section: Introductionmentioning

confidence: 99%

Controllable Epitaxial Growth of Large‐Area MoS₂/WS₂ Vertical Heterostructures by Confined‐Space Chemical Vapor Deposition

Zhang

Huangfu

et al. 2021

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“…Nevertheless, to date there are limited studies on such interlayer optical and electronic responses. [254][255][256][257][258] Furthermore, the highly anisotropic electrical and optical properties in MMCs integrated with 0D (quantum dots) or 1D organic and/or inorganic and perovskite semiconductor materials could open up a new path for next-generation electronic applications. Overall, the very recent exciting achievements in the field of few-layer MMCs showed a great potential for their application in next-generation electronic, optoelectronic, and emerging nanophotonics, including valley electronics, solar cells, sensors, and nonlinear optical applications.…”

Section: Discussionmentioning

confidence: 99%

Recent Advances in 2D Metal Monochalcogenides

Sarkar

Stratakis

2020

Advanced Science

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The family of emerging low‐symmetry and structural in‐plane anisotropic two‐dimensional (2D) materials has been expanding rapidly in recent years. As an important emerging anisotropic 2D material, the black phosphorene analog group IV A –VI metal monochalcogenides (MMCs) have been surged recently due to their distinctive crystalline symmetries, exotic in‐plane anisotropic electronic and optical response, earth abundance, and environmentally friendly characteristics. In this article, the recent research advancements in the field of anisotropic 2D MMCs are reviewed. At first, the unique wavy crystal structures together with the optical and electronic properties of such materials are discussed. The Review continues with the various methods adopted for the synthesis of layered MMCs including micromechanical and liquid phase exfoliation as well as physical vapor deposition. The last part of the article focuses on the application of the structural anisotropic response of 2D MMCs in field effect transistors, photovoltaic cells nonlinear optics, and valleytronic devices. Besides presenting the significant research in the field of this emerging class of 2D materials, this Review also delineates the existing limitations and discusses emerging possibilities and future prospects.

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“…It was manifested that this unique structure of 2D SnS NS/2D MoS 2 NS heterostructure could not only significantly promote effective charge separation and the photoluminescence quenching of MoS 2 , but also remarkably enhance optical nonlinearities compared with individual MoS 2 and SnS. [127]…”

Section: Loaded Modelmentioning

confidence: 99%

“…Moreover, 2D SnS NSs or nanoflakes have also been introduced to fabricate SnS-based heterostructures in a loaded model for distinctly improved performances, such as 2D SnS NS/ carbonized bacterial cellulose (CBC) nanofiber heterostructures, [114] 2D SnS NS/C nanofiber composites, [28] 2D SnS NS/ 2D GeS NS heterostructures, [108] 2D SnS NS/2D MoS 2 NS heteostructures, [119,127] 2D SnS NS/1D aminated C heterostructures, [115] 2D SnS/1D hollow C microtube heterostructures, [111] 2D SnS NS/2D graphene heterostructures, [128] 2D SnS NS/1D CNT heterostructures, [112] etc. In 2021, Yuan et al [114] elaborately designed and rationally synthesized free-standing film consisting of 2D SnS NSs and CBC nanofibers by a hot bath reaction followed by carbonization at high temperature (600-800 C).…”

Section: Loaded Modelmentioning

confidence: 99%

“…In addition, a vertical heterostructure composed of 2D SnS NS and 2D MoS 2 NS was designed and fabricated based on the preferential adsorption of S powder by the precursor, MoS 2 . [127] The schematic diagram of the fabrication procedure of 2D SnS NS/ 2D MoS 2 NS heterostructure is presented in Figure 8h. It has three steps: i) sulfurization of raw material MoO 3 was carried out to fabricate a MoS 2 monolayer on a SiO 2 /Si substrate [129,130] ; ii) the preferential adsorption of S on the MoS 2 monolayer; iii) S-preloaded MoS 2 was converted into the 2D SnS/2D MoS 2 vertical heterostructure after the flow of SnCl 4 vapor.…”

Section: Loaded Modelmentioning

confidence: 99%

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Nanoengineering of Tin Monosulfide (SnS)‐Based Structures for Emerging Applications

Zhu

et al. 2021

Small Science

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Tin-based binary chalcogenide Sn-X (X ¼ S, Se, Te) compounds have attracted extensive interest in the optical, optoelectronic, catalysis, and flexible systems due to their intriguing performances. [1][2][3][4][5][6][7] The Sn-X (X ¼ S, Se, Te) compounds are typically layered materials and usually have three crystalline phases: hexagonal, monoclinic, and orthorhombic; orthorhombic phase is denoted by chemical formula SnX, and hexagonal and monoclinic phases are labeled as SnX 2 . [8] Until now, SnSe and SnTe compounds have already achieved great progress in many fields, especially for thermoelectronics and ferroelectrics, [9][10][11][12] and many important reviews have been reported on SnSe and SnTe compounds due to their rapid development. [8,[13][14][15][16] For example, in 2020, Chen et al. [14] summarized a comprehensive overview of controlled synthesis, characterization, and thermoelectric performance in SnSe. In 2018, Shi et al. [8] summarized the growth, characterization, and applications (photovoltaics, supercapacitors, rechargeable batteries, phase-change memory devices, and topological insulator) of SnSe. In 2018, Li et al. [15] reviewed the development of SnS, SnSe, and SnTe, mainly focusing on the controllable tuning of the electron and phonon transport as well as the challenges for further optimization and practical applications. Among Sn-X (X ¼ S, Se, Te) compounds, tin monosulfide (SnS) as a typical black phosphorus analogue, has also received intensive scientific attention due to its unique properties, such as inexpensive, sustainable, suitable bandgap between Si (1.12 eV) and GaAs (1.43 eV), [17] high absorption coefficient (10 À4 cm À1 ), [18] strong mechanical properties, and anisotropic optoelectronic, [19][20][21] which are of great value in optoelectronics, catalysis, sensors, and nanomedicines. [7,[22][23][24][25][26][27] In addition, layered SnS with suitable spacing structures hold promising potentials in the field of lithium (Li)-ion batteries and sodium (Na)-ion batteries due to their relatively high electrical conductivity and theoretical capacity. [28][29][30][31][32] However, although popular SnS has achieved great progress in a variety of fields, few comprehensive reviews have hitherto focused on the field of SnS-based nanostructures and their fascinating applications.Inspired by important reviews on SnSe reported by Chen [14] and Li [8] in recent years, we comprehensively summarized the synthesis, characterization, and the latest progress of SnS-based nanostructures, as shown in Figure 1. First, the most commonly employed techniques (hydrothermal, vapor deposition, electrostatic assembly, etc.) for preparing SnS and SnS-based nanostructures are presented in detail with their recent progress. Furthermore, the fundamental properties (crystal structure, electronic band structure, optical property, and Raman spectroscopy) and diverse applications (batteries, solar cells, catalysis, optoelectronics, sensors, ferroelectrics, thermoelectrics, nonlinear properties, and biomedical applicatio...

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Vertical Heterostructure of SnS–MoS₂ Synthesized by Sulfur-Preloaded Chemical Vapor Deposition

Cited by 24 publications

References 62 publications

Controllable Epitaxial Growth of Large‐Area MoS₂/WS₂ Vertical Heterostructures by Confined‐Space Chemical Vapor Deposition

Controllable Epitaxial Growth of Large‐Area MoS₂/WS₂ Vertical Heterostructures by Confined‐Space Chemical Vapor Deposition

Recent Advances in 2D Metal Monochalcogenides

Nanoengineering of Tin Monosulfide (SnS)‐Based Structures for Emerging Applications

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Vertical Heterostructure of SnS–MoS2 Synthesized by Sulfur-Preloaded Chemical Vapor Deposition

Cited by 24 publications

References 62 publications

Controllable Epitaxial Growth of Large‐Area MoS2/WS2 Vertical Heterostructures by Confined‐Space Chemical Vapor Deposition

Controllable Epitaxial Growth of Large‐Area MoS2/WS2 Vertical Heterostructures by Confined‐Space Chemical Vapor Deposition

Recent Advances in 2D Metal Monochalcogenides

Nanoengineering of Tin Monosulfide (SnS)‐Based Structures for Emerging Applications

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Product

Resources

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Vertical Heterostructure of SnS–MoS₂ Synthesized by Sulfur-Preloaded Chemical Vapor Deposition

Controllable Epitaxial Growth of Large‐Area MoS₂/WS₂ Vertical Heterostructures by Confined‐Space Chemical Vapor Deposition

Controllable Epitaxial Growth of Large‐Area MoS₂/WS₂ Vertical Heterostructures by Confined‐Space Chemical Vapor Deposition