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Thermal-protective and oxygen-resistant nanocoating using silica-nanocomposites for laser thinning of polymorphic molybdenum ditellurides
- Title
- Thermal-protective and oxygen-resistant nanocoating using silica-nanocomposites for laser thinning of polymorphic molybdenum ditellurides
- Authors
- Heo; Soyoung; Kim; Seulbi; Lee; Seung Yeon; Kwak; In Hye; Baik; Jaeyoon; Yang; Heejun; Park; Ji Hun; Cho; Suyeon
- Ewha Authors
- 조수연; 박지훈
- SCOPUS Author ID
- 조수연; 박지훈
- Issue Date
- 2023
- Journal Title
- Applied Surface Science
- ISSN
- 0169-4332
- Citation
- Applied Surface Science vol. 638
- Keywords
- Fe(III)-TA coating; Laser-thinning; Phase transition; Thickness control; Transition metal dichalcogenides
- Publisher
- Elsevier B.V.
- Indexed
- SCIE; SCOPUS
- Document Type
- Article
- Abstract
- Laser irradiation has been investigated as a method of fabricating atomically thin crystals from layered two-dimensional (2D) materials with precise thickness control. However, during laser irradiation, inevitable structural changes can occur in the 2D materials due to the high thermal energy, altering their physical and chemical properties and introducing disorder, which has hindered the study and use of the intrinsic properties of atomically thin materials. In this study, we report a laser thinning method using a new coating material, a layered silica-based nanocomposite (SNC), that preserves the pristine crystal structure of a polymorphic 2D material, MoTe2, down to an atomically thin geometry. We confirmed that the nano-porous coating of layered silica-based nanocomposite (SNC) behaved as a good thermal-protective and oxygen-resistant material during the laser thinning process using various experimental techniques, atomic force microscopy, Raman spectroscopy and scanning photoelectron microscopy with synchrotron radiation. Accordingly, our SNC coating of 2D materials is a promising way to engineer the phase and geometry of polymorphic 2D materials, enabling versatile applications in various optoelectronic, spintronic, and electronic devices. © 2023 Elsevier B.V.
- DOI
- 10.1016/j.apsusc.2023.157958
- Appears in Collections:
- 공과대학 > 화공신소재공학과 > Journal papers
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