Biosorption for Wastewater Contaminants. Группа авторов

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Название Biosorption for Wastewater Contaminants
Автор произведения Группа авторов
Жанр Биология
Серия
Издательство Биология
Год выпуска 0
isbn 9781119737612



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Barley straw Copper 80% (Pehlivan et al., 2012) Coconut shell fibers Chromium 80% (Mohan et al., 2006)
Animal waste Metal Adsorption capacity Reference
Pretreated fish bones Copper 150.7 mg/g. (Kizilkaya et al., 2010)
Dried animal bones Zinc 0.1764 mmol/g. (Banat et al., 2002)
Crab shell Cobalt 322.6 mg/g (Vijayaraghavan et al., 2006)
Pretreated arca shell biomass Lead 18.33 mg/g (Dahiya et al., 2008)
Animal bone Nickel 7.22 mg/g (Al‐Asheh et al., 1999)

      Biocomposites consist of composite materials up of multiple ingredients that are mixed to make a new product that outperforms the individual constituent materials. They constitute biomass‐based products that are biodegradable, high‐performing, and environmentally friendly and can be utilized for wastewater treatment. Biopolymers such as cellulose, chitosan, starch, chitin, alginate, and others continue to be the most important part of biocomposites. Biopolymers’ advantages include their non‐toxicity, availability, economics, and environmentally friendly nature (Zhang et al., 2013).

      The amount and accessibility of binding sites on the surface of an adsorbent determine the biosorption technique. Usage of biosorbents in their natural state has shown a number of drawbacks due to their poor biosorption potential and unpredictable physical stability. Modifying the surface features of biosorbents can have a huge impact on the biosorbents’ ability to remove metal particles (Gupta et al., 2002). Several researchers concentrated on altering the biomass chemically such that structural stability and effective heavy metal ion biosorption capability can be achieved.

      Desorption and Regeneration

      The ability of biosorbents to recover after use is one of their most important achievements. Adsorbate is cleared off the biosorbent surface after use, and the biosorbent reverts to its original structure and efficiency (Adewuyi, 2020).Biosorbents’ economic value and sustainability are primarily determined by the number of cycles they can be reused. It is essential to develop an effective desorption method. High performance is not enough for a biosorbent; it also needs to be reusable. As a result, when choosing biosorbents, desorption and regeneration are the important processes to consider. Still, some of them are difficult to regenerate, making their long‐term usage doubtful since they would need to be discarded after a few cycles. Disposing of such materials can result in contamination of the environment. The separation of spent biosorbents and the regeneration and recycling of the medium after the sorption process are very significant.

      Eluent utilization is now the most frequently used desorption mechanism. Choosing the right eluent is essential and depends on the form of biosorbent, adsorbent, and biosorption mechanism. A proper eluent should not harm or modify the biosorbent structure, it should be environmentally friendly and affordable, it should have a high level of adsorbing ability, it should not alter adsorbing or biosorbing substances, and it must be easily disconnected. To dislodge metal ions while concurrently replenishing the filled biosorbent, chemicals like hydrochloric acid and sodium hydroxide and chelators like EDTA have been utilized (Ahemad and Kibret, 2013).

      Approximating the cost of biosorption and biosorbents is a challenging process that is rarely published. Cost assessment depends on many factors that make generalization difficult. Variables such as process handling, storage, energy use, repair, optimization of process, rejuvenation, discharge, and desorption are considered when evaluating cost. The type of water or effluent to be treated, as well as the amount, will affect the cost. Capital costs and operating costs, on the other hand, are determined by the type and size of the treatment plant.

      It is preferred to employ wastes as a substrate for processing biosorbents in order to lower process expenses. Agricultural waste, home trash, and industrial waste, such as bacterial drainage from fermentation, fungal waste from food manufacturing, and waste from other industrial processes, can all be used to make biosorbents. Waste management is a significant environmental issue, and using these wastes addresses the concern while also lowering the cost of manufacturing biosorbents for treating water.