Novel soy protein isolate/sodium alginate-based functional aerogel for efficient uptake of organic dye from effluents

Bacterial cellulose and keratin reinforced PAM hydrogels for advanced dye removal: Insights from batch and QCM analyses

Industrial wastewater, particularly from textile industries, contains toxic dyes that require practical and sustainable removal technologies. Hydrogels are potential materials for this purpose due to their high water absorption capacity, but conventional designs suffer from poor mechanical strength and limited dye adsorption efficiency. In this study, we developed a bio-based hydrogel composite by reinforcing polyacrylamide (PAM) with bacterial cellulose (BC) and keratin intermediate filaments (KIF) derived from human hair. This hybrid material enhances both mechanical integrity and adsorption performance. Batch adsorption tests showed a high dye removal efficiency of 60 mg/g for methylene blue over 12 h. In contrast, QCM analysis demonstrated rapid adsorption equilibrium (15 s) under continuous flow conditions, confirming its potential for real-time wastewater treatment. The optimized 2 % KIF hydrogel achieved a compressive strength of 0.4 MPa, forming a porous structure that supports multiple adsorption-desorption cycles for reuse. Adsorption followed pseudo-second-order and Freundlich isotherm models, indicating a heterogeneous mechanism driven by electrostatic interactions and π-π stacking. By integrating sustainable biopolymers, this composite hydrogel overcomes traditional hydrogels' mechanical and functional limitations, offering an eco-friendly solution for continuous wastewater treatment and industrial dye removal.

Polydopamine modified coconut shell biochar decorated with ZIF-8 for improved adsorption of malachite green and rhodamine B from aqueous solution

Although various biochars from different biomass materials have been developed to remediate dye-contaminated environments, the removal capabilities of pristine biochar for dyes urgently require further enhancement due to insufficient surface adsorption sites. To introduce more adsorption sites, this work proposes a simple approach to fabricate coconut shell biochar (CSB) based adsorbent by anchoring zeolitic imidazolate framework-8 (ZIF-8) via the active sites provided by polydopamine (PDA)-coated CSB. The nucleation sites provided by the PDA layer promote the dispersion of ZIF-8 on the surface of CSB, resulting in sufficient adsorption sites for removing malachite green (MG) and rhodamine B (RB) from wastewater. The resulting CSB/PDA/ZIF-8 demonstrates a large specific surface area (749.54 m2 g-1) and outstanding adsorption capacities for MG (1568 mg g-1) and RB (1496 mg g-1). Furthermore, CSB/PDA/ZIF-8 adsorbents can maintain a satisfactory removal rate for MG (91%) and RB (77%) even after five reuses. The analysis of the adsorption mechanism exhibits that electrostatic interactions, hydrogen bonds, coordination bonds, and π-π stacking are of significance for adsorbing MG and RB. Therefore, CSB/PDA/ZIF-8 is a promising candidate for dye wastewater treatment, while this work provides guidance for the high-quality utilization of biomass materials.

Magnetic coconut shell biochar/sodium alginate composite aerogel beads for efficient removal of methylene blue from wastewater: Synthesis, characterization, and mechanism

The challenges of recovering powdered biochar and its limited adsorption capacity are major obstacles to the application of agricultural waste in dye adsorption. To address these issues, this work fabricates Fe3O4-modified coconut shells biochar (mCSB)/sodium alginate (SA) aerogel beads using an in-situ crosslinking-gelation method and freeze-drying technology for methylene blue (MB) removal from wastewater. The spherical mCSB/SA aerogel beads with good magnetic properties (12.8 emu·g-1) can be easily separated from aqueous solutions, thereby completely avoiding the hazard of secondary pollution and device obstruction associated with powdered adsorbents. The absorption capability of MB by mCSB/SA aerogel beads was analyzed and optimized at different conditions. Furthermore, the maximum adsorption capacity of mCSB/SA aerogel beads is 625 mg·g-1 for MB, following the Langmuir isotherm model (R2 = 0.9997). Additionally, the adsorption process of MB on mCSB/SA aerogel beads is found to be spontaneous and endothermic, following the pseudo-second-order kinetic (R2 = 0.9991). Encouragingly, the adsorption efficiency of mCSB/SA aerogel beads remains above 95 % even after 5 times of reusability cycles, demonstrating excellent regeneration ability. This work proposes a straightforward and scalable fabrication strategy to convert agricultural waste into efficient adsorbents for wastewater treatment, adhering to the principles of sustainable development.

Preparation of protein-based aerogels and regulation and application of their absorption properties: a review

Challenges still persist in the preparation of healthy foods through the structuring of liquid oils, and the encapsulation and delivery of functional components. However, protein-based aerogels (PAs) with unique nutritional and health properties as well as various kinds of tunable absorption properties hold promise for solving these problems. In this review, the methods and characteristics of aerogels prepared from various animal and plant proteins were reviewed. In addition, considering the satisfactory structure of amyloid and its outstanding gelation and absorption properties, we proposed accelerating the development of amyloid aerogels in the future. Then, the relationship between their microstructure (specific surface area, pore characteristics, and stability) and absorption properties was discussed. The methods of regulating the absorption properties of PA by hydrogel preparation process, drying technology and surface coating were also emphasized. Finally, we summarized the research advances in PAs for liquid oil structuring and functional ingredient delivery, and provided an outlook for PAs development. The selection of suitable proteins and effective regulation of absorption properties are crucial considerations for improving the applicability of PAs. This review serves as a theoretical reference for the development of healthy, multifunctional and practicable PAs and their products.

Establishing robust ZnO-sodium alginate nanocomposite for dye wastewater treatment: characterization, RSM methodology, and mechanism evaluation

In today's world, water is a highly valued resource, and enhancing the quality of this natural endowment is a significant concern and a worldwide endeavor. This study sought to purify real wastewater and water tainted with methylene blue (MB) by immobilizing ZnO nanoparticles onto an alginate matrix using a straightforward approach and a three-dimensional structure. After analyzing the impact ofH 2 O 2 , it was determined that 93.84% of MB was successfully removed (time = 120 min, dye concentration = 15 mg/L, catalyst amount = 2.5 g). The effects of inorganic ions and water types were investigated to simulate real wastewater conditions, and the catalyst performed satisfactorily. Alginate played a significant role in selectively removing dye, and the catalyst effectively removed 80.36% of MB and, in contrast, 20% of methyl orange (MO). The practical application of the catalyst was evaluated in textile wastewater treatment, and the catalyst showed satisfactory performance. An average 2.49% reduction in dye removal was observed after five stages of using the catalyst, demonstrating the beads' excellent stability. The composites were subjected to free radical trapping experiments to ascertain the active species. According to the results,h + and · OH acted as the main reaction species in the degradation of MB. At the end, the synergistic mechanism of adsorption and degradation in MB removal was presented.

Preparation and characterization of oat hulls-filled-sodium alginate biocomposite microbeads for the effective adsorption of toxic methylene blue dye

In this work, the performance of oat hull-filled sodium alginate (SA-O) biocomposite microbeads in the adsorptive removal of methylene blue (MB) dye was examined. First, oat hulls were pulverized and biocomposite gels containing different weight ratios of oat hulls (10 %, 20 %, and 30 %, concerning the SA amount) were prepared by dispersing them in SA solution by ultrasonic homogenization method. Finally, gels were cross-linked by dropping into a 2 % CaCl2 solution. The study revealed that the optimal adsorbent dosage was 0.025 g/50 mL, pH was roughly 6-8, and the contact time was 120 min. According to isotherm models, the non-linear Sips and Langmuir model was more appropriate compare to other isotherms from error analysis, with a maximum adsorption capacity of 687.65 mg/g and 757.57 mg/g at 298 K, respectively. Furthermore, the non-linear kinetic data and error analyzes demonstrated that the process followed the pseudo-second-order kinetic. The adsorption process was exothermic (∆H°=-17.71 kJ/mol) and spontaneous (∆G°=-26.23 kJ/mol) at 298 K, based on thermodynamic characteristics. Furthermore, reusability investigations demonstrated that the adsorbent retained its performance with no major changes in characteristics. This work reveals that highly efficient, low-cost, sustainable, and eco-friendly SA-O composites with properties might be useful adsorbents for cationic dye adsorption.

One-pot hydrothermal synthesis of FeNbO4 microspheres for effective sonocatalysis

FeNbO4 sonocatalysts were successfully synthesized by a simple hydrothermal route at pH values of 3, 5, 7, 9 and 11. The catalysts were characterized by XRD, XPS, TEM, SEM, N2 adsorption and DRS to analyse the effect of pH parameters on the physicochemical properties of the materials during hydrothermal synthesis. The sonocatalytic activity of FeNbO4 microspheres was evaluated by using acid orange 7 (AO7) as the simulated contaminant. The experimental results showed that the best sonocatalytic degradation ratio (97.45%) of organic dyes could be obtained under the conditions of an initial AO7 concentration of 10 mg L-1, an ultrasonic power of 200 W, a catalyst dosage of 1.0 g L-1, and a pH of 3. Moreover, the sonocatalysts demonstrated consistent durability and stability across multiple test cycles. After active species capture experiments and calculation of the energy band, a possible mechanism was proposed based on the special Fenton-like mechanism and the dissociation of H2O2. This research shows that FeNbO4 microspheres can be used as sonocatalysts for the purification of organic wastewater, which has a promising application prospect.