Tuning the Band Structure of Zn-Doped SnS2 Nanosheet-Based Thin Films by Atomic Layer Deposition for Photoelectric Devices

Tuning the Band Structure of Zn-Doped SnS2 Nanosheet-Based Thin Films by Atomic Layer Deposition for Photoelectric Devices

Two-dimensional tin disulfide (SnS2) is attracting attention from researchers in various fields due to its physical, optical, and electrical properties. In addition, research suggests that SnS2 doped with various metals can be used in a wide range of applications. However, few studies of the doping...

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Veröffentlicht in:ACS applied nano materials 2022-12, Vol.5 (12), p.18199-18208
Hauptverfasser: Choi, Yeonsik, Kim, Byunguk, Lee, Dowwook, Kang, Sooyeon, Kim, Jungtae, Bae, Jangho, Jeon, Hyeongtag
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container_issue 12
container_start_page 18199
container_title ACS applied nano materials
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creator Choi, Yeonsik
Kim, Byunguk
Lee, Dowwook
Kang, Sooyeon
Kim, Jungtae
Bae, Jangho
Jeon, Hyeongtag
description Two-dimensional tin disulfide (SnS2) is attracting attention from researchers in various fields due to its physical, optical, and electrical properties. In addition, research suggests that SnS2 doped with various metals can be used in a wide range of applications. However, few studies of the doping process in tin sulfide thin films with various doping concentrations using atomic layer deposition (ALD) and the super-cycle method have been published. Here, we describe the deposition of pristine SnS2 using ALD and analyze crystallinity, chemistry, and optical and electrical properties of SnS2 doped with various concentrations of zinc by controlling the ratio of SnS2 and ZnS using super-cycle recipes. As the doping concentration increased, a cubic-phase ZnS layer was formed, and chemical binding energies increased, revealing an n-type doping effect. As the doping concentration increased, the transmittance of the thin film increased by up to 80.5%, and the optical band gap increased to 3.43 eV. In addition, the valence-band edge energy increased up to 2.02 eV, and n-type characteristics appeared as the doping concentration of zinc increased as determined by calculation of the electronic band structure. These zinc-doped nanoscale SnS2 materials have potential for optoelectronic applications.
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In addition, research suggests that SnS2 doped with various metals can be used in a wide range of applications. However, few studies of the doping process in tin sulfide thin films with various doping concentrations using atomic layer deposition (ALD) and the super-cycle method have been published. Here, we describe the deposition of pristine SnS2 using ALD and analyze crystallinity, chemistry, and optical and electrical properties of SnS2 doped with various concentrations of zinc by controlling the ratio of SnS2 and ZnS using super-cycle recipes. As the doping concentration increased, a cubic-phase ZnS layer was formed, and chemical binding energies increased, revealing an n-type doping effect. As the doping concentration increased, the transmittance of the thin film increased by up to 80.5%, and the optical band gap increased to 3.43 eV. 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