Abstract

Clay minerals have large surface areas that contribute to their high adsorption capacity. Pure clays were often used. However, their prices remain expensive. However, the natural clay minerals that are locally available can have economic and environmental benefits for textile wastewater treatment. The tested natural clays had given low removal yields. Therefore, we wanted to test particular rich organic matter clay for adsorbing azo dye, which is a very toxic molecule. In order to make the use of this clay type have a better efficiency for removal of this dye from the polluted waters, the optimal conditions had been specified. The results indicated that advised conditions were as follows: 5 min was the contact time of dye-clay; the better adsorbent masses were 0.25 g and 0.5 g per 100 ml solution for raw (ANb) and purified clays (ANp), respectively; the initial dye concentrations were 1 gL−1 for raw clay and 50 mgL−1 for purified clay; pH solution had any effect on the yield of dye removal only when raw clay was used; however, acid environment was advised when purified clay was the adsorbent and for the two tested clays about 20–30°C was the better solution temperature. X-Ray diffraction, Fourier transform infrared (FTIR) spectroscopy, and scanning electron microscopy (SEM) analysis confirmed that functional groups of clay adsorbed the dye. Langmuir maximum adsorption capacities of ANb and ANp were found to be 397 mgg−1 and 132.3 mgg−1 at pH 7 and 5, respectively. Raw and chemically activated samples gave similar results. Adsorption of ANb and ANp data showed better agreement with the pseudo-second-order kinetic model. Thermodynamic parameters of the two adsorbents confirmed that the adsorption was endothermic (ΔH > 0) and spontaneous (ΔG0 < 0). Energy level was high when purified clay was used; however, it was significantly lower when the adsorbent was raw clay. Therefore, it was likely that adsorption by carbonates and organic matter involved small energy amounts. Comparing between these and other previous results, Jebel Louka natural clay type is better recommended for MR removal from textile wastewater, since the removal yield was about 98%. Hence, this tested clay type could provide an alternative low-cost material that could be used in treatment of the textile wastewater rich in MR and the obtained adsorption model and desorption tests provided a background for pilot and industrial scale applications.

Highlights

  • Annual productions of the quantities and varieties of textile dyes are more and more important [1, 2] and have extensive industrial applications. ese coloring molecules are often very toxic

  • There are more than 100,000 commercially existing dyes and over one million tons of dyes are manufactured per year, of which 50% are textile dyes [7, 8]. erefore, during the dying process, significant amounts of toxic stable molecules were lost in used water [9]

  • Electric conductivity (EC) shows that purified clay ANp is more salty (0.1) than ANb clay (0.4)

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Summary

Introduction

Annual productions of the quantities and varieties of textile dyes are more and more important [1, 2] and have extensive industrial applications. ese coloring molecules are often very toxic. Ese coloring molecules are often very toxic These toxic chemical agents discharged into textile used water can often endanger the equilibrium of natural ecosystem [3] and have negative impacts on living organisms and environment [4,5,6]. Because of the molecules complexity and the affinity degrees of colorants to the textile fibers, the discharge of this water kind in the environment is very worrying today [10, 11]. These pollutants of used water need to be well treated to obtain permissible concentrations before discharge

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