Iranian Journal of

Background and Objective: In the present research, the synthesis and characterization of ZnS nanoparticles in zinc blend crystallite phase via hydrothermal method were reported. Advanced oxidation processes using nanophotocatalysts are one of the most efficient methods for removing the dyes with complex organic compounds from textile and industrial wastewaters. The photocatalytic performance of nanoparticles is drastically affected by their structural and optical properties. One of the most important features affecting the photocatalytic degradation of nanoparticles is their optical bandgap width, which is an important factor in the radiant photons in the visible and UV region and the production of active radicals to destroy the complex carbon pollutants. The optical bandgap width, like other properties of nanoparticles is affected by three important geometric parameters, including particle size, dimension and shape. It is also a function of synthetic chemistry, i.e. the precursors and the fabrication methods. The aim of the present study was to investigate the nanostructure of zinc-sulfide synthesized nanoparticles, optical properties and photocatalytic effect on the degradation of Methylene Orange dye.
Materials and Methods: The experiment of degradation of dye consisted of 70 mg of synthesized nanoparticles in 100 mL of dye solution containing 3.75 ppm of Methylene Orange dye at pH = 5.5. The experimental steps were repeated three times. Nanostructure characterization of three-dimension ZnS nanoparticles was specified by X-ray diffraction, scanning electron microscopy, energy dispersive x-ray spectroscopy, transmission electron microscopy, Furrier transform infrared, ultraviolet-visible spectroscopy and N₂ adsorption-desorption.
Results: The lattice characteristics such as density, specific surface area, size, strain, stress and deformation energy density are specified using Williamson-Hall (W-H) and Halder-Wagner (H-W) analysis. The photocatalytic degradation rate (k) of Methylene Orange was calculated to be 0.052 1/min, whilst after 60 minutes about 95% of the dye was photodegraded. The N₂ adsorption-desorption calculations determined the mean pore diameter, specific surface area (S_BET) and total porosity volume as 20.69 nm, 19.12 m²/g and 0.065 m³/g, respectively. The bandgap of fabrication ZnS has been evaluated from the Tauc's equation to be 3.47 eV. Compared with ZnS nanoparticles made by the hydrothermal method in the wurtzite crystallite phase (sample 2), the synthesized sample (sample 1) shows less lattice strain and stress, less crystallite size and also revealed the higher photocatalytic activity.
Conclusion: The pure zinc-sulfide nanoparticles without metal or ceramic dopants in the cubic zinc-blend crystallite phase are synthesized using the hydrothermal method. The precursors used in the synthesis of zinc-sulfide nanoparticles include zinc chloride and thioacetamide in the presence of oleic acid as a collecting agent. High photocatalytic activity of ZnS nanoparticles was confirmed by the degradation or dechlorination of Methylene Orange solution under UV light irradiation. Compared to similar studies, the results show that reducing the optical bandgap from 3.84 eV to 3.47 eV increases the degradation rate from 0.031 to 0.052. In this study, it was shown that synthesized zinc-sulfide nanoparticles by hydrothermal method, was able to decrease optical gap bandwidth and subsequently increased photocatalytic activity.

Background and Objective: The increasing accumulation of spent coffee grounds (SCG) has raised serious environmental concerns. This study aimed to evaluate the efficiency of the hydrothermal carbonization process in converting SCG into a valuable solid fuel..
Materials and Methods: An experimental study was conducted using the design of experiments (DOE) approach and response surface methodology (RSM). The effects of key independent variables—including temperature (180–290 °C), reaction time (30–90 min), and liquid-to-solid ratio (L:S, 1:1–15:1)—on the properties of the produced hydrochar were investigated. A total of 20 experiments were carried out, and physicochemical analyses were performed on both the hydrochar and the process water.
Results: The results indicated that the quadratic model demonstrated strong predictive capability for hydrochar yield (HY) and higher heating value (HHV) (R² > 0.98). Analysis of variance showed that all three independent variables had significant effects on HY and HHV. The produced hydrochar showed HHV of 17.9–28.5 MJ/kg and HY of 17.5–77.2%. Response surface methodology identified 235 °C, 180 min, and L:S 4:1 as optimal for desirable HY and HHV. Optimization indicated 229 °C, 160 min, and L:S 4:1 yielded hydrochar with 27.8 MJ/kg HHV, 67.9% HY, with 0.891 desirability. CHNSO analysis showed a decrease in H/C and O/C ratios and an increase in surface area from 2.4 to 12.6 m²/g.
Conclusion: Given the favorable HHV of the produced hydrochar, it can be concluded that the proposed process is an effective method for converting biomass into solid fuel.