Authors:
Baltaeva Umida Ismoilovna, P. Divya, G. V. Kanmani, Mika Sillanpää
Addresses:
Department of Applied Mathematics and Mathematical Physics, Urgench State University, Urgench, Xorazm Region, Uzbekistan. Department of Chemistry, Dhaanish Ahmed College of Engineering, Chennai, Tamil Nadu, India. Department of Physics, Dhaanish Ahmed College of Engineering, Chennai, Tamil Nadu, India. Department of Chemical Engineering Technology, University of Johannesburg, Johannesburg, Gauteng, South Africa.
Abstract:
This study examines the production and complete characterization of tin sulfide nanotubes prepared by the solvothermal method. The study aims to investigate the chemical reaction between tin chloride dihydrate and thiourea under controlled thermal conditions. The dataset used in this research contains 315 different experimental observations in the form of spectral intensity counts, diffraction angles, and morphological measurements. Ultraviolet-Visible spectroscopy, Photoluminescence analysis, Powder X-ray diffraction, and Scanning Electron Microscopy were used to test the material's properties. The measurements show that the band energy gap is 1.77 electron volts, and there is a strong red emission in the light spectrum. The crystal system is proven to be orthorhombic Herzenbergite, as supported by structural analysis and morphological imagery, which show a cluster of rod-shaped formations. Chemical bonds are further confirmed by infrared spectroscopy through characteristic vibrational peaks. The above detailed study provides background knowledge of the optical and structural properties of such nanostructures, which will be used in the future in semiconductors.
Keywords: Tin Sulfide; Solvothermal Synthesis; Chemical Bonds; Crystal System; Photoluminescence Analysis; Infrared Spectroscopy; Solvothermal Technique; Vibrational Peaks.
Received on: 02/11/2024, Revised on: 27/12/2024, Accepted on: 22/03/2025, Published on: 03/03/2026
DOI: 10.64091/ATIAS.2026.000291
AVE Trends in Intelligent Applied Sciences, 2026 Vol. 2 No. 1 , Pages: 1–10