Low-temperature wafer-scale synthesis of two-dimensional SnS<sub>2</sub>

Pyeon, Jung Joon; Baek, In‐hwan; Lim, Weon Cheol; Chae, Keun Hwa; Han, Seong Ho; Lee, Ga Yeon; Kim, Jin Sang; Choi, Ji Won; Chung, Taek; Han, Jeong Hwan; Kang, Chong Yun; Kim, Seong Keun

doi:10.1039/c8nr05450a

Cited by 31 publications

(31 citation statements)

References 36 publications

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“…Each layer corresponds to a (040) plane 31 of SnS for an interspacing of 2.8 Å and a (001) plane of SnS 2 for an interspacing of 5.9 Å. 4 The transformed SnS layers are observed not only near the surface but also at the interface with the SiO 2 substrate despite insufficient cycles for transformation. The transformed SnS is even observed below the SnS 2 that had not yet transformed.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Cation-Regulated Transformation for Continuous Two-Dimensional Tin Monosulfide

et al. 2020

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The synthesis of a continuous and high-quality large-area layer is a key research area in the field of two-dimensional (2D) metal chalcogenides. To date, several techniques, including chemical vapor deposition and sulfurization/ selenization, have been proposed for the synthesis of 2D metal chalcogenides. These techniques are based on the substitutional reaction of anions, that is, replacement of oxygen with chalcogen elements. This study uses a new approach based on cation-regulated transformation. An SnS 2 layer, a parent material, is grown by atomic layer deposition, followed by reaction with bis(1-dimethlamino-2-methyl-2-propoxy)tin(II) at a temperature of 270 °C to form SnS. The reaction occurs predominantly along grain boundaries. The transformation self-terminates once the pregrown SnS 2 is completely consumed. The devices utilizing the transformed layers, such as gas sensors and thin-film transistors, exhibit a p-type behavior, supporting full transformation of n-type SnS 2 into p-type SnS. Consequently, complete transformation into a continuous and single-phase SnS layer is demonstrated by the cation-regulated transformation approach. This approach provides possibilities to expand approaches to the synthesis of more diverse 2D metal chalcogenides and the modulation of their properties.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Cation-Regulated Transformation for Continuous Two-Dimensional Tin Monosulfide

et al. 2020

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“…This allows the formation of MoO 3 /MoS 2 heterostructures when oxidizing few-layer MoS 2 crystals. Similarly, two-step growth of 3 nm SnS 2 crystals is achieved by sulfurization of ALD-grown tin oxides (SnO and SnO 2 ) on Al 2 O 3 substrate . Two-step growth of 2D perovskites has also been reported by many groups. − Ha et al reported the synthesis of 2D perovskite nanoplatelets from 2D PbI 2 .…”

Section: Synthesismentioning

confidence: 93%

Synthesis and Applications of Wide Bandgap 2D Layered Semiconductors Reaching the Green and Blue Wavelengths

Yang

Warner

2020

ACS Appl. Electron. Mater.

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Two-dimensional semiconductors with a layered structure are now among the most extensively studied materials. The unique structural form of 2D layered semiconductors provides several benefits over other existing materials as key components in next-generation nanodevices such as transistors, photodetectors, solar cells, light emitting devices, molecular sensors, and optical imaging sensors. However, most of these studies concentrate on narrow bandgap semiconductors (bandgap E g < 2 eV) that emit/absorb in the red and infrared regions. Recently, more research has focused on wide bandgap 2D layered semiconductors, as they have demonstrated great potential in applications in electronics and optoelectronics for the green and blue wavelength regions. This Review summarizes the 2D layered materials that have been experimentally proven as wide bandgap semiconductors, including GaS, GaSe, InSe

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“…In this work, atomic layer deposition (ALD) is employed for the growth of MoS 2 films. Although chemical vapor deposition (CVD) is still the preferred synthesizing technique to achieve the best quality 2D TMDCs in large areas, ,, in the quest of Ångstrøm level thickness control and highly conformal layers (suitable for 3D structures) while maintaining a low thermal budget, required for industry processes, ALD has also been gaining attention in recent years. − We comprehensively study the impact of device processing conditions on the chemistry involved at the metal-to-MoS 2 interface and connect the two to the current–voltage ( I – V ) results, obtained from electrically characterizing the fabricated FETs, with ALD-based MoS 2 films and Ti/Au contacts. In pursuit of optimizing the contacts to our MoS 2 , we investigate the influence of thermal annealing and plasma cleaning the contacts (with O 2 and Ar) on the overall device electrical performance while scaling down the Ti interlayer thickness.…”

Section: Introductionmentioning

confidence: 99%

On the Contact Optimization of ALD-Based MoS₂ FETs: Correlation of Processing Conditions and Interface Chemistry with Device Electrical Performance

Mahlouji

Zhang

Verheijen

et al. 2021

ACS Appl. Electron. Mater.

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Despite the extensive ongoing research on MoS 2 field effect transistors (FETs), the key role of device processing conditions in the chemistry involved at the metal-to-MoS 2 interface and their influence on the electrical performance are often overlooked. In addition, the majority of reports on MoS 2 contacts are based on exfoliated MoS 2 , whereas synthetic films are even more susceptible to the changes made in device processing conditions. In this paper, working FETs with atomic layer deposition (ALD)-based MoS 2 films and Ti/Au contacts are demonstrated, using current–voltage ( I – V ) characterization. In pursuit of optimizing the contacts, high-vacuum thermal annealing as well as O 2 /Ar plasma cleaning treatments are introduced, and their influence on the electrical performance is studied. The electrical findings are linked to the interface chemistry through X-ray photoelectron spectroscopy (XPS) and scanning transmission electron microscopy (STEM) analyses. XPS evaluation reveals that the concentration of organic residues on the MoS 2 surface, as a result of resist usage during the device processing, is significant. Removal of these contaminations with O 2 /Ar plasma changes the MoS 2 chemical state and enhances the MoS 2 electrical properties. Based on the STEM analysis, the observed progress in the device electrical characteristics could also be associated with the formation of a continuous TiS x layer at the Ti-to-MoS 2 interface. Scaling down the Ti interlayer thickness and replacing it with Cr is found to be beneficial as well, leading to further device performance advancements. Our findings are of value for attaining optimal contacts to synthetic MoS 2 films.

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Low-temperature wafer-scale synthesis of two-dimensional SnS₂

Cited by 31 publications

References 36 publications

Cation-Regulated Transformation for Continuous Two-Dimensional Tin Monosulfide

Cation-Regulated Transformation for Continuous Two-Dimensional Tin Monosulfide

Synthesis and Applications of Wide Bandgap 2D Layered Semiconductors Reaching the Green and Blue Wavelengths

On the Contact Optimization of ALD-Based MoS₂ FETs: Correlation of Processing Conditions and Interface Chemistry with Device Electrical Performance

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Low-temperature wafer-scale synthesis of two-dimensional SnS2

Cited by 31 publications

References 36 publications

Cation-Regulated Transformation for Continuous Two-Dimensional Tin Monosulfide

Cation-Regulated Transformation for Continuous Two-Dimensional Tin Monosulfide

Synthesis and Applications of Wide Bandgap 2D Layered Semiconductors Reaching the Green and Blue Wavelengths

On the Contact Optimization of ALD-Based MoS2 FETs: Correlation of Processing Conditions and Interface Chemistry with Device Electrical Performance

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Product

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Low-temperature wafer-scale synthesis of two-dimensional SnS₂

On the Contact Optimization of ALD-Based MoS₂ FETs: Correlation of Processing Conditions and Interface Chemistry with Device Electrical Performance