Noble metal-coated MoS2 nanofilms with vertically-aligned 2D layers for visible light-driven photocatalytic degradation of emerging water contaminants

Islam, Ashraful; Church, Jared; Cui, Han; Chung, Hee Suk; Ji, Eunji; Kim, Jong Hun; Choudhary, Nitin; Lee, Gwan Hyoung; Lee, Woo Hyoung; Jung, Yeonwoong

doi:10.1038/s41598-017-14816-9

Cited by 54 publications

(30 citation statements)

References 52 publications

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“…The resistance of these devices varied from 185 to 490 MΩ with an average of 347 MΩ as shown in the box plot of Fig. 1 c. The measured values of resistance for our MoS 2 devices are consistent with what has been reported in the literature 34 , 49 – 51 , 53 , 54 . After characterizing the as-prepared samples, we doped the MoS 2 film by immersing it in BV solution for 36 h (see “Method” section for detail) and measured their electrical transport properties.…”

Section: Resultssupporting

confidence: 88%

Scalable lateral heterojunction by chemical doping of 2D TMD thin films

Chamlagain

Withanage

Johnston

et al. 2020

Sci Rep

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Scalable heterojunctions based on two-dimensional transitional metal dichalcogenides are of great importance for their applications in the next generation of electronic and optoelectronic devices. However, reliable techniques for the fabrication of such heterojunctions are still at its infancy. Here we demonstrate a simple technique for the scalable fabrication of lateral heterojunctions via selective chemical doping of TMD thin films. We demonstrate that the resistance of large area MoS 2 and MoSe 2 thin film, prepared via low pressure chalcogenation of molybdenum film, decreases by up to two orders of magnitude upon doping using benzyl viologen (BV) molecule. X-ray photoelectron spectroscopy (XPS) measurements confirms n-doping of the films by BV molecules. Since thin films of MoS 2 and MoSe 2 are typically more resistive than their exfoliated and co-evaporation based CVD counterparts, the decrease in resistance by BV doping represents a significant step in the utilization of these samples in electronic devices. Using selective BV doping, we simultaneously fabricated many lateral heterojunctions in 1 cm 2 MoS 2 and 1 cm 2 MoSe 2 films. The electrical transport measurements performed across the heterojunctions exhibit current rectification behavior due to a band offset created between the doped and undoped regions of the material. Almost 84% of the fabricated devices showed rectification behavior demonstrating the scalability of this technique.

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Section: Resultssupporting

confidence: 88%

Scalable lateral heterojunction by chemical doping of 2D TMD thin films

Chamlagain

Withanage

Johnston

et al. 2020

Sci Rep

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show abstract

“…It is also interesting to note that the integral intensity ratio of the A 1g mode to the E 1 2g mode (A 1g /E 1 2g ) is very high ∼4.4, indicating the dominant presence of out-of-plane vibrations (A 1g ). This high value of A 1g /E 1 2g is a signature of the enlarged degree of freedom for lattice vibration in vertically aligned 2D layers, indicating the pronounced exposure of layer edge sites on the film surface. , The detailed crystalline structure of MoS 2 films with vertically aligned 2D layers was inspected by TEM characterization. A cross-sectional view of the MoS 2 film/Au taken in an annular dark-field TEM (ADF-TEM) mode is shown in Figure (d), revealing a distinguishable image contrast in between the MoS 2 and Au regions.…”

Section: Resultsmentioning

confidence: 99%

Improving Electrochemical Pb²⁺ Detection Using a Vertically Aligned 2D MoS₂ Nanofilm

et al. 2019

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Recent advancements in MoS 2 nanofilms have aided in the development for important water-related environmental applications. However, a MoS 2 nanofilm-coated sensor has yet to have been applied for heavy metal detection in water-related environmental samples. In this study, a novel vertically aligned two-dimensional (2D) MoS 2 (edge exposed) nanofilm was applied for in situ lead ion (Pb 2+ ) detection. The developed sensor showed an excellent linear relationship toward Pb 2+ between 0 and 20 ppb at −0.45 V vs Ag/AgCl using square wave anodic stripping voltammetry (SWASV) with the improved limit of detection (LOD) of 0.3 ppb in a tap water environment. The vertically aligned 2D MoS 2 sensor exhibited improved detection sensitivity (2.8 folds greater than a previous metallic [Bi] composite electrode) with lower relative standard deviation for repetitive measurements (n = 11), indicating enhanced reproducibility for Pb 2+ detection. The vertically aligned 2D MoS 2 layers exhibited 2.6 times higher sensitivity than horizontally aligned 2D MoS 2 (basal plane exposed). Density functional theory calculations demonstrated that adsorption energy of Pb on the MoS 2 side edge was much higher (4.11 eV) than those on the basal plane (0.36 and 0.07 eV). In addition, the band gap center of vertical MoS 2 was found to be higher than the Pb 2+ → Pb reduction potential level and capable of reducing Pb 2+ . Overall, the newly developed vertically aligned 2D MoS 2 sensor showed excellent performance for detecting Pb 2+ in a real drinking water environment with good reliability.

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“…2D TMDs obtained in this manner exhibit horizontally-aligned basal planes of well-resolved layers; for example, horizontally-aligned 2D MoS 2 layers of ~7–8 nm thickness obtained from the sulfurization of ~2.5 nm thick Mo have been confirmed by atomic force microscopy (AFM) and cross-sectional TEM characterization (Supplementary Information, S4). Maintaining the small thickness of metal seeds is critically important to ensure that 2D TMD layers grow in horizontal orientation as identified in our previous studies 32,34 . In this case, weak molecular vdW attraction will be responsible for holding the 2D basal planes of diminished defect density to the SiO 2 substrate surface, enabling facile water penetration in between them.…”

Section: Discussionmentioning

confidence: 96%

Centimeter-scale Green Integration of Layer-by-Layer 2D TMD vdW Heterostructures on Arbitrary Substrates by Water-Assisted Layer Transfer

Kim

Okogbue

et al. 2019

Sci Rep

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Two-dimensional (2D) transition metal dichalcogenide (2D TMD) layers present an unusually ideal combination of excellent opto-electrical properties and mechanical tolerance projecting high promise for a wide range of emerging applications, particularly in flexible and stretchable devices. The prerequisite for realizing such opportunities is to reliably integrate large-area 2D TMDs of well-defined dimensions on mechanically pliable materials with targeted functionalities by transferring them from rigid growth substrates. Conventional approaches to overcome this challenge have been limited as they often suffer from the non-scalable integration of 2D TMDs whose structural and chemical integrity are altered through toxic chemicals-involved processes. Herein, we report a generic and reliable strategy to achieve the layer-by-layer integration of large-area 2D TMDs and their heterostructure variations onto a variety of unconventional substrates. This new 2D layer integration method employs water only without involving any other chemicals, thus renders distinguishable advantages over conventional approaches in terms of material property preservation and integration size scalability. We have demonstrated the generality of this method by integrating a variety of 2D TMDs and their heterogeneously-assembled vertical layers on exotic substrates such as plastics and papers. Moreover, we have verified its technological versatility by demonstrating centimeter-scale 2D TMDs-based flexible photodetectors and pressure sensors which are difficult to fabricate with conventional approaches. Fundamental principles for the water-assisted spontaneous separation of 2D TMD layers are also discussed.

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Noble metal-coated MoS2 nanofilms with vertically-aligned 2D layers for visible light-driven photocatalytic degradation of emerging water contaminants

Cited by 54 publications

References 52 publications

Scalable lateral heterojunction by chemical doping of 2D TMD thin films

Scalable lateral heterojunction by chemical doping of 2D TMD thin films

Improving Electrochemical Pb²⁺ Detection Using a Vertically Aligned 2D MoS₂ Nanofilm

Centimeter-scale Green Integration of Layer-by-Layer 2D TMD vdW Heterostructures on Arbitrary Substrates by Water-Assisted Layer Transfer

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Noble metal-coated MoS2 nanofilms with vertically-aligned 2D layers for visible light-driven photocatalytic degradation of emerging water contaminants

Cited by 54 publications

References 52 publications

Scalable lateral heterojunction by chemical doping of 2D TMD thin films

Scalable lateral heterojunction by chemical doping of 2D TMD thin films

Improving Electrochemical Pb2+ Detection Using a Vertically Aligned 2D MoS2 Nanofilm

Centimeter-scale Green Integration of Layer-by-Layer 2D TMD vdW Heterostructures on Arbitrary Substrates by Water-Assisted Layer Transfer

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Improving Electrochemical Pb²⁺ Detection Using a Vertically Aligned 2D MoS₂ Nanofilm