Water pollution due to the presence

Water pollution due to the presence of heavy metals is a major environmental concern. Presence of metals may originate from several industries and its occurrence has become a major risk to plant, animal and human life due to the bioaccumulation tendency and toxicity of heavy metals. It is imperative that proper treatment techniques are developed for effective removal of heavy metals from municipal and industrial effluents before discharge as the existing conventional methods offer limitations both in terms of efficacy and economics [1]. Use of biological materials as bioadsorbent for the removal of heavy metals has received significant attention in the recent years because of the good performance, eco-friendly nature and low cost for the adsorbent [2]. Microbial biomass, both metabolically inactive or dead and living are able to bind and accumulate metal species and can be used as biosorbents in addition to the more commonly used sustainable materials derived from biomass. The dead biomass offer more advantages as it can be obtained as by-products from fermentation or biological oxidation, no nutrient supplementation is required and these can be easily regenerated [3] and [4]. The present work has focused on the use of such dead biomass obtained as a residue during the treatment of organic contaminants using the modified activated sludge [5]. The model contaminants selected in the present work are Cu(II) and Cr(VI) based on the significant importance in the industrial activities. Cu ions are non-degradable and persistent leading to serious environmental problems, which makes the effective removal from the wastewater of primary importance [4]. Cr(VI) is also of a great concern because of its toxicity to humans, animals, plants and microorganisms [6]. Cr(VI) has also shown some carcinogenic effects. The present work has concentrated on developing an efficient process for the removal of these two metal ions based on the use of modified sludge biomass (MSB) as adsorbent.

Immobilization of biosorbents is very essential for the industrial application because large volumes are required to be treated [7] and it becomes imperative that the biosorbent is easily separated from wastewater to be available for reuse. Use of porous media is an important requirement for the attachment of biomass to significantly enhance the efficacy of separation. Polymeric media would be a suitable material for these purposes because of the offered large area and production at low cost with precision and repeatability. Immobilization of biomass can be performed using different entrapment materials such as alginates, polyacrylamide, polysulfone, polyvinyl formal, polyacrylamide, cellulose, polyvinyl alcohol (PVA) and carboxymethylcellulose sodium salt (CMC) [8], [9], [10], [11], [12] and [13]. CMC is a biodegradable, naturally present polymer with large number of functional groups being present on the surface [14], [15] and [16], which makes CMC a good candidate for immobilization. Al-Hakawati and Banks [7] studied the application of different polymers such as polyvinyl formal, polysulfone, polyurethane, alginate, polyacrylamide, k-carrageenan and polyethyleneimine (PEI) for entrapment of biomass and reported that immobilization using different polymer medium at high rate was difficult due to agglomeration of biomass. In addition, microscopic examination of the polymer/biomass entrapment showed little sign of a porous matrix hindering the possible rapid diffusion of metal ions to the biomass binding sites. Thus it is important to properly select the polymer support as well as control the synthesis conditions so that the desired characteristics are obtained. Entrapment of biomass in polyvinyl alcohol (PVA) and cellulosic material could be effective also giving enhanced mechanical strength and the biosorption characteristics could be superior leading to higher removal extents of the heavy metals from wastewater and soil [15]. Additional benefits include low material cost, rapid formation of beads by simple procedure and easy application in fluidized bed reactors due to higher elasticity and high strength characteristics of PVA beads [11]. Earlier studies have mostly concentrated on pretreatments or modifications in the biomass with an objective of obtaining enhanced surface area which may enhance the sorption capacity for the removal of pollutants from aqueous solution [17]. Though different materials have been used for immobilization of different biomass, not much information has been reported on the use of a non-living modified sludge biomass and the comparison of the different polymeric media as support for the immobilization. Based on this analysis, different approaches of immobilization were applied for the attachment of MSB and the efficacy was investigated for metal removal in terms of the removal efficiency and the equilibrium isotherm as well as kinetic parameters. The effect of different operating parameters (i.e., pH, adsorbent d