SnS2 Nanoparticles and Thin Film for Application as an Adsorbent and Photovoltaic Buffer

Abstract: Energy consumption and environmental pollution are major issues faced by the world. The present study introduces a single solution using SnS2 for these two major global problems. SnS2 nanoparticles and thin films were explored as an adsorbent to remove organic toxic materials (Rhodamine B (RhB)) from water and an alternative to the toxic cadmium sulfide (CdS) buffer for thin-film solar cells, respectively. Primary characterization tools such as X-ray photoelectron spectroscopy (XPS), Raman, X-ray diffraction (… Show more

“…Recent studies present SnS 2 as a buffer layer for the Cu­(In,Ga)­Se 2 (CIGS) solar cell device with similar performance to CdS . In this work, Gedi et al fabricated a solar cell with SnS 2 , presenting an open-circuit voltage ( V OC ) of 0.41 V, a short-circuit current density ( J SC ) of 25.67 mA cm –2 , a fill factor (FF) of 49%, and a conversion efficiency (η) of ∼5.1%.…”

“…Complementarily, SnS 2 is an n-type semiconductor with a hexagonal crystal structure with a = 0.364 nm, b = 0.364 nm, c = 0.589 nm lattice parameters, and P3m1 space group (Figure c). SnS 2 has a flexible wide band gap in the range of 1.8–2.9 eV, varying according to the deposition methods. − This compound is synthesized using inexpensive elements, simple controllable chemical stoichiometry, and consistent environmental stability. SnS 2 has a plethora of potential applications ranging from diodes, photodectors, gas sensors, batteries, supercapacitors, field effect transistors, and buffer layers for heterojunction solar cells .…”

“…SnS 2 has a flexible wide band gap in the range of 1.8–2.9 eV, varying according to the deposition methods. − This compound is synthesized using inexpensive elements, simple controllable chemical stoichiometry, and consistent environmental stability. SnS 2 has a plethora of potential applications ranging from diodes, photodectors, gas sensors, batteries, supercapacitors, field effect transistors, and buffer layers for heterojunction solar cells . SnS 2 synthesis can be achieved by different processes, such as CVD, wet chemical processes, and spray pyrolysis .…”

“…SnS 2 has a plethora of potential applications ranging from diodes, photodectors, gas sensors, batteries, supercapacitors, field effect transistors, and buffer layers for heterojunction solar cells . SnS 2 synthesis can be achieved by different processes, such as CVD, wet chemical processes, and spray pyrolysis . The SnS 2 -calculated (DFT) band structure is shown in Figure d, where one can observe the occurrence of an indirect gap.…”

Scanning Tunneling Spectroscopy Method for the Prediction of Semiconductor Heterojunction Performance as a Prequel for Device Development

“…Recent studies present SnS 2 as a buffer layer for the Cu­(In,Ga)­Se 2 (CIGS) solar cell device with similar performance to CdS . In this work, Gedi et al fabricated a solar cell with SnS 2 , presenting an open-circuit voltage ( V OC ) of 0.41 V, a short-circuit current density ( J SC ) of 25.67 mA cm –2 , a fill factor (FF) of 49%, and a conversion efficiency (η) of ∼5.1%.…”

“…Complementarily, SnS 2 is an n-type semiconductor with a hexagonal crystal structure with a = 0.364 nm, b = 0.364 nm, c = 0.589 nm lattice parameters, and P3m1 space group (Figure c). SnS 2 has a flexible wide band gap in the range of 1.8–2.9 eV, varying according to the deposition methods. − This compound is synthesized using inexpensive elements, simple controllable chemical stoichiometry, and consistent environmental stability. SnS 2 has a plethora of potential applications ranging from diodes, photodectors, gas sensors, batteries, supercapacitors, field effect transistors, and buffer layers for heterojunction solar cells .…”

“…SnS 2 has a flexible wide band gap in the range of 1.8–2.9 eV, varying according to the deposition methods. − This compound is synthesized using inexpensive elements, simple controllable chemical stoichiometry, and consistent environmental stability. SnS 2 has a plethora of potential applications ranging from diodes, photodectors, gas sensors, batteries, supercapacitors, field effect transistors, and buffer layers for heterojunction solar cells . SnS 2 synthesis can be achieved by different processes, such as CVD, wet chemical processes, and spray pyrolysis .…”

“…SnS 2 has a plethora of potential applications ranging from diodes, photodectors, gas sensors, batteries, supercapacitors, field effect transistors, and buffer layers for heterojunction solar cells . SnS 2 synthesis can be achieved by different processes, such as CVD, wet chemical processes, and spray pyrolysis . The SnS 2 -calculated (DFT) band structure is shown in Figure d, where one can observe the occurrence of an indirect gap.…”

Scanning Tunneling Spectroscopy Method for the Prediction of Semiconductor Heterojunction Performance as a Prequel for Device Development

“…Organic dyes are broadly applied in industries, including pharmaceuticals, paper, leather, textiles, makeup, and plastics, as a colorant agent [1][2][3][4][5][6]. Up to 20% of total dye output is wasted during industrial processing, causing pollution and eutrophication and disturbing aquatic habitats [7][8][9].…”

Synthesis of BiFeO₃/ZnMgAl-LDH nanocomposite for instantaneous decolorization of methylene blue by ultrasonic induced adsorption system: characterization and equilibrium studies

Structural, microstructural, and optical properties of SnS films deposited by nanoink’s spraying with a post-growth temperature treatment