Crystals (Jun 2024)

Abundant Catalytic Edge Sites in Few-Layer Horizontally Aligned MoS<sub>2</sub> Nanosheets Grown by Space-Confined Chemical Vapor Deposition

  • Alin Velea,
  • Angel-Theodor Buruiana,
  • Claudia Mihai,
  • Elena Matei,
  • Teddy Tite,
  • Florinel Sava

DOI
https://doi.org/10.3390/cryst14060551
Journal volume & issue
Vol. 14, no. 6
p. 551

Abstract

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Recently, a smart strategy for two-dimensional (2D) materials synthesis has emerged, namely space-confined chemical vapor deposition (CVD). Its extreme case is the microreactor method, in which the growth substrate is face-to-face stacked on the source substrate. In order to grow 2D transition metal dichalcogenides by this method, transition metal oxides, dispersed in very small amounts on the source substrate, are used as source materials in most of the published reports. In this paper, a colloidal dispersion of MoS2 in saline solution is used and MoS2 nanosheets with various shapes, sizes (between 5 and 60 μm) and thicknesses (2–4 layers) have been synthesized. Small MoS2 flakes (regular or defective) are present on the surface of the nanosheets. Catalytic sites, undercoordinated atoms located at the edges of MoS2 flakes and nanosheets, are produced in a high number by a layer-plus-island (Stranski–Krastanov) growth mechanism. Several double-resonance Raman bands (at 147, 177, 187, 225, 247, 375 cm−1) are assignable to single phonon processes in which the excited electron is elastically scattered on a defect. The narrow 247 cm−1 peak is identified as a topological defect-activated peak. These findings highlight the potential of defect engineering in material property optimization, particularly for solar water splitting applications.

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