Removal of cadmium and nickel from aqueous solution using expanded perlite

-This work aimed to determine the maximum content of cobalt that can be incorporated by ion exchange in zeolites H-USY, H-Beta, H-Mordenite, and H-ZSM-5. To reach this goal, batch isotherms at 75ºC were constructed after addition of zeolite samples in flasks filled with cobalt nitrate solution. The equilibrium data were fitted to Langmuir, Freundlich, and Tóth adsorption isotherm models. Langmuir was the best model for zeolites H-Beta, H-Mordenite, and H-ZSM-5, whereas experimental data for H-USY were better fitted to the Freundlich isotherm model. From the isotherms, it was possible to determine the maximum cobalt exchange level (q max ) that can be incorporated in each zeolite through ion exchange. In this sense, H-USY presented the highest q max value (2.40 meq/g zeol ), while H-ZSM-5 showed the lowest one (0.64 meq/g zeol ).These results also show the influence of the zeolite framework related to the channel system, pore opening, presence of cavities and secondary porosity and SiO 2 /Al 2 O 3 ratio (SAR) on the maximum capacity and behavior of cobalt ion exchange in protonic zeolites.

Section: Isotherm Constructionmentioning

confidence: 99%

Determination of the maximum retention of cobalt by ion exchange in h-zeolites

Zola

Barros

Sousa-Aguiar

et al. 2012

“…Various low cost adsorbents have been investigated for removing Cd, Pb and other metals from aqueous solutions: bentonite (Naseem and Tahir, 2001), expanded perlite (Torab-Mostaedi et al, 2010), mud (Salim, 1986), volcanic ash soil (Cajuste et al, 1996), pine bark (Al-Asheh et al, 1998), waste tire rubber ash (Mousavi et al, 2010), freshwater macrophytes (Schneider and Rubio, 1999), bacteria (Yilmaz et al, 2010), aquatic mosses (Al-Asheh et al, 1998;Martins and Boaventura, 2002), peat moss (McKay and Porter, 1997), alum sludge (Chu, 1999), soybean hulls, cottonseed hulls, rice straw and sugarcane bagasse (Marshall and Champagne, 1995), rice husk (Vieira et al, 2012;Senthil Kumar et al, 2010), olive stones (Calero et al, 2009), activated carbon from lignocellulosic residues (Giraldo and MorenoPiraján, 2008;Attia et al, 2010). The literature shows an extensive list of biomass used in metal biosorption; the novelty of this work is exactly the use of an aquatic moss, a less studied material.…”

Section: Introductionmentioning

confidence: 99%

Kinetic modelling of cadmium and lead removal by aquatic mosses

Martins

Vilar

Boaventura

2014

-Because biosorption is a low cost and effective method for treating metal-bearing wastewaters, understanding the process kinetics is relevant for design purposes. In the present study, the performance of the aquatic moss Fontinalis antipyretica for removing cadmium and lead from simulated wastewaters has been evaluated. Five kinetic models (first-order, pseudo-first-order, Elovich, modified Ritchie second-order and pseudo-second-order) were fitted to the experimental data and compared. Previously, the effect of parameters such as the initial solution pH, contact time, and initial metal ion concentration on biosorption was investigated. The initial pH of the solution was found to have an optimum value in the range of 4.0-6.0. The equilibrium sorption capacity of cadmium and lead by Fontinalis antipyretica increased with the initial metal concentration. For an initial metal concentration of 10 mg L -1 , the uptake capacity of the moss, at equilibrium, is the same for both metals (4.8 mg g -1 ). Nevertheless, when the initial concentration increases up to 100 mg L -1 , the uptake of Pb(II) was higher than 78%. The pseudo-second order biosorption kinetics provided the better correlation with the experimental data 2 ( 0.999) ≥ R .

“…The application of various alternative materials for sorption or elimination of metals in wastewater has been investigated due to its numerous economic advantages Zola et al, 2012;Oueslati et al, 2011;Torab-Mostaedi et al, 2010;Attia et al, 2010;Yilmaz et al, 2010;Giraldo and Moreno-Piraján, 2008;Novakovic et al, 2008;Stathi et al, 2007;Ouhadi et al, 2006). The cost of clay is relatively low compared to other alternative adsorbents, including activated charcoal, natural and synthetic zeolites, and ion exchange resins.…”

Section: Introductionmentioning

confidence: 99%

Insight of the removal of nickel and copper ions in fixed bed through acid activation and treatment with sodium of clay

Neto

Vieira

Silva

2014

-The bentonitic clays show good adsorptive characteristics, being used as alternative material for removing metals. This study evaluates several treatments (calcination, acid activation and treatment with sodium) of bentonite type Bofe in the removal of nickel and copper. Analyses were performed for physicochemical characterization of clay using the techniques: X-ray fluorescence (XRF), thermal analysis (TG and DTA), X-ray Diffraction (XRD), the ethylene glycol monoethyl ether (EGME) method, N 2 adsorption (BET) and Scanning Electron Microscopy (SEM). Among the changes induced by acid activation and sodium transformations, the treatment with sodium chloride in fixed bed showed the highest performance in the monocomponent removal of nickel and copper.