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Abstract
Laminated metal dichalcogenides are candidates for different potential applications ranging from catalysis to nanoelectronics. However, efforts are still needed to optimize synthesis methods aiming to control the number of layers, morphology, and crystallinity, parameters that govern the properties of the synthesized materials. Another important parameter is the thickness and the length of the samples with the possibility of large-scale growth of target homogeneous materials. Here, we report a chemical vapor deposition method at atmospheric pressure to produce vertically aligned tin dichalcogenide based-materials. Tin disulfide (SnS2) and tin diselenide (SnSe2) vertically aligned nanosheets have been synthesized and characterized by different methods showing their crystallinity and purity. Homogenous crystalline 2H-phase SnS2 nanosheets with high purity were synthesized with vertical orientation on substrates; sulfur vacancies were observed at the edges of the sheets. Similarly, in the crystalline 2H phase SnSe2 nanosheets selenium vacancies were observed at the edges. Moreover, these nanosheets are larger than the SnS2 nanosheets, show lower nanosheet homogeneity on substrates and contamination with selenium atoms from the synthesis was observed. The synthesized nanomaterials are interesting in various applications where the edge accessibility and/or directionality of the nanosheets play a major role as for example in gas sensing or field emission.
Highlights
Two-dimensional (2D) layered nanostructures have received increasing interest due to their unique nanoscale phenomena and their potential applications ranging from electronics and energy to catalysis
Homogenous crystalline 2Hphase SnS2 nanosheets with high purity were synthesized with vertical orientation on substrates; sulfur vacancies were observed at the edges of the sheets
Our reaction occurs at 450 C, which is a relatively low selenization temperature in the range of temperatures reported for the synthesis of the SnSe2 phase, explaining the observation of a mix of both phases, as we reported in this work
Summary
Two-dimensional (2D) layered nanostructures have received increasing interest due to their unique nanoscale phenomena and their potential applications ranging from electronics and energy to catalysis. Different 2D layered dichalcogenides, such as molybdenum disul de (MoS2),[1] tungsten disul de (WS2),[2] molybdenum diselenide (MoSe2),[3] tungsten diselenide (WSe2),[4] tin disul de (SnS2)[5] and tin diselenide (SnSe2)[6] have been widely studied. The interest in these nanomaterials was trigged by their potential applications in eld-effect transistors (FETs),[7] photodetectors,[8] solar cells,[9,10]. With a direct band gap of 1.4 eV,[15] SnSe2 is attractive in the elds of nanoelectronics and optoelectronics, and due to its structure and low cost, it is a strong candidate for sensing applications.[16]
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