Biosorption for Wastewater Contaminants. Группа авторов

Biosorption for Wastewater Contaminants - Группа авторов


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be taken into account in biosorption, as once the biomass is fully used in repeated cycles it must be substituted. However, it may be applied in other areas, such as particulate board processing, cement, biogas, etc.

      Biosorption is a low‐cost treatment for complicated commercial wastewater with high volumes and low heavy metal concentrations. Metal ions in an aqueous solution are replaced for a counter ion bound to biomass in this process, classified as ion exchange. The efficacy of the various biosorbents is unquestionably essential to the biosorption technology's promising potential. Several types of biomass that are abundant and exhibit strong metal binding characteristics have been recognized. Many natural biomass biosorbents have been established from cellulosic and microbial origins, with effective biosorption features. But several of these biosorbents have shown poor efficiency. Surface changes made to biosorbents have helped enhance their metal‐binding characteristics, as is apparent from extensive research; however, the adjustments increase the average operational costs to match the cost of commercialized ion‐exchange resins. The existence of multifunctional groups on the biomass surface causes it to be non‐selective to a particular metal ion. The biosorbents' non‐selective and unspecific character, as well as their lesser resilience, pose a significant marketing challenge. The creation of biosorption models and the identification of biosorption mechanisms, as well as the identification of better and more selective biosorbents, are all key future research topics for biosorption technology.

      1 Abbas, S.H., Ismail, I.M., Mostafa, T.M., and Sulaymon, A.H. (2014). Biosorption of heavy metals: A review. Journal of Chemical Science and Technology 3 (4): 74–102.

      2 Abdi, O. and Kazemi, M. (2015). A review study of biosorption of heavy metals and comparison between different biosorbents. Journal of Materials and Environmental Science 6 (5): 1386–1399.

      3 Acosta Rodríguez, I., Martínez‐Juárez, V.M., Cárdenas‐González, J.F. et al. (2013). Biosorption of Arsenic(III) from Aqueous Solutions by Modified Fungal Biomass of Paecilomyces sp. Bioinorganic Chemistry and Applications 2013: 1–5. doi:10.1155/2013/376780.

      4 Adewuyi, A. (2020). Chemically modified biosorbents and their role in the removal of emerging pharmaceutical waste in the water system. Water 12 (6): 1551. doi:10.3390/w12061551.

      5 Ahemad, M. and Kibret, M. (2013). Recent trends in microbial biosorption of heavy metals: A review. Biochemistry and Molecular Biology 1 (1): 19–26.

      6  Al‐Asheh, S., Banat, F., and Mohai, F. (1999). Sorption of copper and nickel by spent animal bones. Chemosphere 39: 2087–2096.

      7 Ali Redha, A. (2020). Removal of heavy metals from aqueous media by biosorption. Arab Journal of Basic and Applied Sciences 27 (1): 183–193. doi:10.1080/25765299.2020.1756177.

      8 Anaemene, I.A. (2012). The use of Candida sp. in the biosorption of heavy metals from industrial effluent. European Journal of Experimental Biology 2 (3): 484–488.

      9 Apinthanapong, M. and Phensaijai, M. (2009). Biosorption of copper by spent yeast immobilized in sodium alginate beads. Kasetsart Journal (Natural Science) 43: 326–332.

      10 Arakaki, A.H., Vandenberghe, S., de Soccol, L.P. et al. (2011). Optimization of biomass production with copper bioaccumulation by yeasts in submerged fermentation. Brazilian Archives of Biology and Technology 54 (5): 1027–1034. doi:10.1590/S1516‐89132011000500021.

      11 Aravindhan, R., Fathima, A., Selvamurugan, M. et al. (2012). Adsorption, desorption, and kinetic study on Cr(III) removal from aqueous solution using Bacillus subtilis biomass. Clean Technologies and Environmental Policy 14 (4): 727–735. doi:10.1007/s10098‐011‐0440‐7.

      12 Arbanah, M., Najwa, M., and Ku Halim, K. (2013). Utilization of Pleurotusostreatus in the removal of Cr (VI) from chemical laboratory waste. International Refereed Journal of Engineering Science 2: 29–39.

      13 Argun, M.E., Dursun, S., and Karatas, M. (2009). Removal of Cd (II), Pb (II), Cu (II) and Ni (II) from water using modified pine bark. Desalination 249: 519–527.

      14 Arshad, N. and Imran, S. (2020). Indigenous waste plant materials: An easy and cost‐effective approach for the removal of heavy metals from water. Current Research in Green and Sustainable Chemistry 3: 100040. doi:10.1016/j.crgsc.2020.100040.

      15 Aryal, M. (2020). A comprehensive study on the bacterial biosorption of heavy metals: materials, performances, mechanisms, and mathematical modellings. Reviews in Chemical Engineering 20190016. doi:10.1515/revce‐2019‐0016.

      16 Aryal, M., Ziagova, M.G., and Liakopoulou‐Kyriakides, M. (2012). Cu(II). Biosorption and competitive studies in multi‐ions aqueous systems by Arthrobacter sp. Sphe3 and Bacillus sphaericus cells: equilibrium and thermodynamic studies. Water, Air, and Soil Pollution 223 (8): 5119–5130. doi:10.1007/s11270‐012‐1263‐9.

      17 Babel, S. (2003). Low‐cost adsorbents for heavy metals uptake from contaminated water: a review. Journal of Hazardous Materials 97 (1–3): 219–243. doi:10.1016/S0304‐3894(02)00263‐7.

      18 Banat, F., Al‐Asheh, S., and Mohai, F. (2002). Multi‐metal sorption by spent animal bones. Separation Science and Technology 37: 311–327.

      19 Baroni, L., Cenci, L., Tettamanti, M. et al. (2007). Evaluating the environmental impact of various dietary patterns combined with different food production systems. European Journal of Clinical Nutrition 61 (2): 279–286. doi:10.1038/sj.ejcn.1602522.

      20 Çelekli, A., Yavuzatmaca, M., and Bozkurt, H. (2010). An eco‐friendly process: Predictive modelling of copper adsorption from aqueous solution on Spirulina platensis. Journal of Hazardous Materials 173 (1–3): 123–129. doi:10.1016/j.jhazmat.2009.08.057.

      21 Chen, C. and Wang, J.‐L. (2006). [Cation (K+, Mg2+, Na+, Ca2+) release in Zn(II) biosorption by Saccharomyces cerevisiae]. Huan Jing Ke Xue= Huanjing Kexue 27 (11): 2261–2267.

      22 Chojnacka, K. (2010). Biosorption and bioaccumulation – the prospects for practical applications. Environment International 36 (3): 299–307. doi:10.1016/j.envint.2009.12.001.

      23  Dahiya, S., Tripathi, R.M., and Hegde, A.G. (2008). Biosorption of lead and copper from aqueous solutions by pretreated crab and arca shell biomass. Bioresource Technology 99: 179–187.

      24 Das, N., Vimala, R., and Karthika,: (2008). Biosorption of heavy metals – An overview. Indian Journal of Biotechnology 7: 159–169.

      25 Davis, T.A., Volesky, B., and Mucci, A. (2003). A review of the biochemistry of heavy metal biosorption by brown algae. Water Research 37 (18): 4311–4330. doi:10.1016/S0043‐1354(03)00293‐8.

      26 Dhanarani, S., Viswanathan, E., Piruthiviraj,: et al. (2016). Comparative study on the biosorption of aluminum by free and immobilized cells of Bacillus safensis KTSMBNL 26 isolated from explosive contaminated soil. Journal of the Taiwan Institute of Chemical Engineers 69: 61–67. doi:10.1016/j.jtice.2016.09.032.

      27 Fan, T., Liu, Y., Feng, B. et al. (2008). Biosorption of cadmium(II), zinc(II) and lead(II) by Penicillium simplicissimum: Isotherms, kinetics and thermodynamics. Journal of Hazardous Materials 160 (2–3): 655–661. doi:10.1016/j.jhazmat.2008.03.038.

      28 Farajzadeh, M.A. and Monji, A.B. (2004). Adsorption characteristics of wheat bran towards heavy metal cations. Sep Purif Technol 38: 197–207.

      29 Flouty, R. and Estephane, G. (2012). Bioaccumulation and biosorption of copper and lead by a unicellular algae Chlamydomonas reinhardtii in single and binary metal systems: A comparative study. Journal of Environmental Management 111: 106–114. doi:10.1016/j.jenvman.2012.06.042.

      30 Fu, F. and Wang, Q. (2011). Removal of heavy metal ions from wastewaters: A review. Journal of Environmental Management 92 (3): 407–418. doi:10.1016/j.jenvman.2010.11.011.

      31 Gaensly, F., Picheth, G., Brand, D. et al. (2014). The uptake of different iron salts by the yeast Saccharomyces cerevisiae. Brazilian Journal of Microbiology 45 (2): 491–494. doi:10.1590/S1517‐83822014000200016.

      32 Gao,


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