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The textile industry is one of the largest in many low and middle-income countries, especially in Asia, second only to agriculture. Textile wastewater is discharged into the environment due to the lack of affordable and sustainable solutions to adsorb or remove the dye from the water. Biochar is generated by pyrolysis of organic material from plant waste in low-oxygen conditions, and is considered carbon-negative. Biochar for dye adsorption in textile wastewater effluent was proven to be highly effective. However, adsorption efficiency varies with experimental parameters, therefore there is a gap in application especially in small dye houses. Efforts should be made to find innovative and affordable solution to make the textile industry more sustainable, by developing methods for collection and reuse, recycle and upcycle of textile waste, by reducing the consumption of water, energy and chemicals and by developing methods for treatment of the textile wastewater.
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Czasopismo
Rocznik
Tom
Strony
36--46
Opis fizyczny
Bibliogr. 43 poz.
Twórcy
autor
- School of Mechanical Engineering, Faculty of Engineering, Tel Aviv University, Tel Aviv 69978, Israel
autor
- School of Mechanical Engineering, Faculty of Engineering, Tel Aviv University, Tel Aviv 69978, Israel
autor
- School of Mechanical Engineering, Faculty of Engineering, Tel Aviv University, Tel Aviv 69978, Israel
autor
- School of Mechanical Engineering, Faculty of Engineering, Tel Aviv University, Tel Aviv 69978, Israel
Bibliografia
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- [9] Rubeena KK, Reddy PHP, Laiju AR, Nidheesh PV. Iron impregnated biochars as heterogeneous Fenton catalyst for the degradation of acid red 1 dye. Journal of Environmental Management 226 (2018), 320-328.
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- [15] Inyang M, Dickenson E. The potential role of biochar in the removal of organic and microbial contaminants from potable and reuse water: A review. Chemosphere 134 (2015), 232-240.
- [16] Kimbell LK, Tong Y, Mayer BK, McNamara PJ. Biosolids-Derived Biochar for Triclosan Removal from Wastewater. Environmental Engineering Science 35 (2018), 513-524.
- [17] Palansooriya KN, Yang Y, Tsang YF, Sarkar B, Hou D, Cao X, Meers E, Rinklebe J, Kim KH, Ok YS. Occurrence of contaminants in drinking water sources and the potential of biochar for water quality improvement: A review. Critical Reviews in Environmental Science and Technology 50 (2019), 549-611.
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- [24] Ajmal A, Majeed I, Malik RN, Idriss H, Nadeem MA Principles and mechanisms of photocatalytic dye degradation on TiO2 based photocatalysts: A comparative overview. RSC Advances 4 (2014), 37003-37026.
- [25] Mishra G, Tripathy M. A critical review of the treatment for decolorization of textile effluent. Colourage 40 (1993), 35-38.
- [26] Sewu DD, Boakye P, Woo SH. Highly efficient adsorption of cationic dye by biochar produced with Korean cabbage waste; Bioresource Technology 224 (2017), 206-213.
- [27] Rubeenaa KK, Reddya PHP, Laijub AR, Nidheeshc PV. Iron impregnated biochars as heterogeneous Fenton catalyst for the degradation of acid red 1 dye. Journal of Environmental Management 226 (2018), 320-328.
- [28] Han L, Xue S, Zhao S, Yan J, Qian L, Chen M. Biochar Supported Nanoscale Iron Particles for the Efficient Removal of Methyl Orange Dye in Aqueous Solutions. PLoS ONE 10 (2015), 1-7
- [29] Yu J, Zhang X, Wang D, Li P. Adsorption of methyl orange dye onto biochar adsorbent prepared from chicken manure. Water Science and Technology 77 (2018), 1303-1312.
- [30] Leng L, Yuan X, Huang H, Shao J, Wang H, Chen X, Zeng G. Bio-char derived from sewage sludge by liquefaction: Characterization and application for dye adsorption. Applied Surface Science 346 (2015). 223-231.
- [31] Mathew M, Desmond RD, Caxton M. Removal of methylene blue from aqueous solutions using biochar prepared from Eichhorrnia crassipes (Water Hyacinth)-molasses composite: Kinetic and equilibrium studies. African Journal of Pure and Applied Chemistry 10 (2016), 63-72.
- [32] Zazycki MA, Godinho M, Perondi D, Foletto EL, Collazzo GC, Dotto GL. New biochar from pecan nutshells as an alternative adsorbent for removing reactive red 141 from aqueous solutions. Journal of Cleaner Production 171 (2018). 57-65.
- [33] Kyi PP, Quansah JO, Lee CG, Moon JK, Park SJ. The Removal of Crystal Violet from Textile Wastewater Using Palm Kernel Shell-Derived Biochar. Applied Sciences 10 (2020), 2251.
- [34] Mahmoud ME, Nabil GM, El-Mallah NM, Bassiouny HI, Kumar S, A-Fattah TM. Kinetics, isotherm, and thermodynamic studies of the adsorption of reactive red 195 A dye from water by modified switchgrass biochar adsorbent. Journal of Industrial and Engineering Chemistry 37 (2016), 156-167.
- [35] Thivyaa J, Vijayaraghavan J. Single and binary sorption of reactive dyes onto red seaweed-derived biochar: multi-component isotherm and modelling. Desalination and Water Treatment 156 (2019), 87-95.
- [36] Mubarak NM, Fo YT, Al-Salim HS, Sahu JN, Abdullah EC, Nizamuddin S, Jayakumar NS, Ganesan P. Removal of Methylene Blue and Orange-G from Waste Water Using Magnetic Biochar. International Journal of Nanoscience 14 (2015), 1-4.
- [37] Rebitanim NZ, Ghani WAWAK, Mahmoud DK, Rebitanim NA, Salleh MM. Adsorption of methylene blue by agricultural solid waste of pyrolyzed EFB biochar. Journal of Purity, Utility Reaction and Environment 1 (2012), 376-390.
- [38] Nautiyal P, Subramanian KA, Dastidar MG. Adsorptive removal of dye using biochar derived from residua algae after in-situ transesterification: Alternate use of waste of biodiesel industry. Journal of Environmental Management 182 (2016), 187-197.
- [39] Oladipo AA, Ifebajo AO, Nisar N, Ajayi OA. High-performance magnetic chicken bone-based biochar for efficient removal of rhodamine-B dye and tetracycline: competitive sorption analysis. Water Science Technology 76 (2017), 373-385.
- [40] Chaukura N, Murimba EC, Gwenzi W. Sorptive removal of methylene blue from simulated wastewater using biochars derived from pulp and paper sludge. Environmental Technology & Innovation 8 (2017), 132-140.
- [41] Sewu DD, Jung H, Kim SS, Lee DS, Woo SH. Decolorization of cationic and anionic dye-laden wastewater by steam activated biochar produced at an industrial-scale from spent mushroom substrate. Bioresource Technology 277 (2019), 77-86.
- [42] Luo XP, Fu SY, Du YM, Guo JZ, Li B. Adsorption of methylene blue and malachite green 400 from aqueous solution by sulfonic acid group modified MIL-101. Microporous and Mesoporous Materials 237 (2017), 268-274.
- [43] Vyavahare GD, Gurav RG, Jadhav PP, Patil RR, Aware CB, Jadhav JP Response surface methodology optimization for sorption of malachite green dye on sugarcane bagasse biochar and evaluating the residual dye for phyto and cytogenotoxicity. Chemosphere 194 (2018), 306-315.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-38336bfe-6ad1-44a0-9991-ac19eed15a9d