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Research Article
Application of Flax (Linum Usitatissimum L.) Straw Derived Activated Carbon Using Phosphoric Acid (H3PO4) for the Removal of Nitrate (NO3-) Ions from Aqueous Solutions
Issue:
Volume 9, Issue 1, April 2025
Pages:
1-17
Received:
22 March 2025
Accepted:
10 April 2025
Published:
29 April 2025
Abstract: Significant health and environmental hazards are associated with nitrate (NO3-) contamination in water, which calls for economical and environmentally friendly treatment techniques. This study investigates using phosphoric acid (H3PO4) activation to turn flax straw (Linum usitatissimum L.), an underutilized agricultural residue, into activated carbon (FS-AC) for the removal of nitrate from aqueous solutions. The FS-AC was prepared by chemical activation under varying conditions (temperature: 400-600°C, H3PO4 concentration: 1-3 M, impregnation ratio: 1:4-1:6) and optimized using response surface methodology (RSM). Characterization via Scanning Electron Microscopy (SEM) revealed a highly porous morphology (surface area: 798.23 m2/g), while X-ray Diffraction (XRD) and Fourier Transform Infrared Spectroscopy (FTIR) confirmed an amorphous carbon structure with oxygen-rich functional groups and residual crystalline phases. Under optimal conditions (532°C, 1 M H3PO4, impregnation ratio 1:5), FS-AC achieved 92.79% nitrate removal at pH 4, 0.25 g/L dose, and 60 min contact time. Adsorption followed the Langmuir isotherm (R2=0.9895), indicating monolayer adsorption, and pseudo-second-order kinetics (R2=0.9408), suggesting chemisorption. Thermodynamic analysis revealed spontaneity (ΔG°: −1.27 to −0.18 kJ/mol) and exothermicity (ΔH°=−14.19 kJ/mol). Generally, the study highlights FS-AC’s competitive performance against biomass-derived carbons, with fixed carbon content up to 34.89%. By converting flax straw waste into an efficient adsorbent, this study addresses dual challenges of agricultural residue management and water pollution, aligning with circular economy principles. Thus, future research should explore scalability, regeneration, and application in real wastewater systems to further validate its industrial viability.
Abstract: Significant health and environmental hazards are associated with nitrate (NO3-) contamination in water, which calls for economical and environmentally friendly treatment techniques. This study investigates using phosphoric acid (H3PO4) activation to turn flax straw (Linum usitatissimum L.), an underutilized agricultural residue, into activated carb...
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Research Article
Characterization and Assessment of Soil Acidity Status Under Different Land UseTypes and Soil Depths in Lalistu Cheri Watershed, Sibu Sire District, Western Ethiopia
Amanuel Tadesse*
,
Achalu Chimdi,
Tilahun Chibsa
Issue:
Volume 9, Issue 1, June 2025
Pages:
18-37
Received:
21 March 2025
Accepted:
7 April 2025
Published:
22 May 2025
DOI:
10.11648/j.ajcbe.20250901.12
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Views:
Abstract: Soil acidity, a significant form of chemical soil degradation, is one of the most pressing challenges in Ethiopia, particularly in the highlands. It severely impacts agricultural productivity across much of the country. Owing to its impact on crop production and productivity, it is a critical issue that requires immediate attention in most highlands in Ethiopia. This study was conducted at the Lalistu Cheri watershed, which is located in the Sibu Sire District of the western zone of the Oromia region, Ethiopia, with the objective of characterizing and assessing the soil acidity status under different land use types and soil depths. Replicated composite soil samples were collected from three representative land use types (cultivated, grazing, and eucalyptus plantation lands) and two soil depths (0-20 and 20-40 cm) by X-patterns along transects and analyzed via standard laboratory procedures. The results revealed spatial variation in the soil properties among the land use types and soil depths. The soils in both cultivated and eucalyptus plantation land were strongly acidic (pH<5.5), whereas those in grazing land were moderately acidic. The highest (54.89%) and lowest (43.73%) clay contents were recorded in the soils of cultivated and grazed lands, respectively, whereas the sand content was greater (36.11%) in the eucalyptus plantation land. The relatively highest bulk density (1.36 g cm-3) was recorded in the grazed land soils, followed by the cultivated land soils (1.32 g cm-3). Both the exchangeable acidity and aluminum content in all land use types decreased with increasing soil depth, which was consistent with their acid saturations. The organic carbon content ranged from 2.30% at the subsurface layer of the cultivated land to 3.44% at the surface layer of the grazing land soils, whereas the total nitrogen content ranged from 0.19% to 0.30%. Available P ranged from 7.31 mg kg-1 to 12.61 mg kg-1. The highest Ca, Mg, Na, and K contents (8.92, 5.76, 0.30, and 1.26 Cmol (+) kg-1, respectively) were recorded in the soils of the grazing land. The amount of PBS used ranged from 35.14% to 78.45%. The CEC and ECEC of the soils in the three land use types also increased consistently with increasing soil depth. Micronutrient concentrations decreased with soil depth. The Fe and Mn contents ranged from 0.54 and 4.42 mg kg-1 in the subsurface layer of the grazing land and eucalyptus plantations, respectively, to 10.58 and 12.14 mg kg-1 in the surface layer of the eucalyptus plantations and grazing land soils, respectively. Cu and Zn also ranged from 1.52 and 0.29 mg kg-1 to 3.16 and 0.85 mg kg-1, respectively. The study suggests that both CL and EPL soils exhibit the highest acidity and require soil management practices, such as lime application, to reduce acidity and improve soil fertility. On the other hand, GL soils show more favorable conditions for nutrient retention and pH.
Abstract: Soil acidity, a significant form of chemical soil degradation, is one of the most pressing challenges in Ethiopia, particularly in the highlands. It severely impacts agricultural productivity across much of the country. Owing to its impact on crop production and productivity, it is a critical issue that requires immediate attention in most highland...
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Research Article
In Vitro Endothelial Differenthelial Assessment on Polyglycerol Sebacate / Polycaprolactone /Gelatin Electospun Scaffold
Issue:
Volume 9, Issue 1, June 2025
Pages:
38-47
Received:
27 December 2024
Accepted:
11 February 2025
Published:
29 May 2025
DOI:
10.11648/j.ajcbe.20250901.13
Downloads:
Views:
Abstract: Due to the prevalence of cardiovascular diseases and their growing trend throughout the world, including Iran, efforts to treat these types of diseases have increased. There are lots of therapies for restoring cardiovascular function include organ transplants, reconstructive surgery, the use of mechanical or artificial devices, and the use of metabolic products. Although these methods are commonly used, they cause problems due to donor limitations, such as biocompatibility, infection, and tissue rejection by the patient. Meanwhile, vascular tissue engineering with the aim of building biocompatible and efficient vessels to replace lost vessels has created high hopes for the treatment of lesions. In this article, we used polyglycerol sebacate polymer (PGS) due to the properties such as high biocompatibility, good cell adhesion, controllable degradation rate and desirable mechanical properties, and combined it with polycaprolactone polymer (PCL) and gelatin to fabricate 3D scaffolds by electrospinning method. We also added vascular endothelial growth factor and then analysed the endothelial differentiation of mesenchymal stem cells. The expression of CD31 and VEGF-R2 genes has been measured by qPCR method, which revealed reasonable results.
Abstract: Due to the prevalence of cardiovascular diseases and their growing trend throughout the world, including Iran, efforts to treat these types of diseases have increased. There are lots of therapies for restoring cardiovascular function include organ transplants, reconstructive surgery, the use of mechanical or artificial devices, and the use of metab...
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