Development of Nano-Hydroxyapatite Embedded Gelatin

Nov 22, 2015 - exists with two different oxidation states, viz., Cr(VI) and. Cr(III).1 The non-toxic form of ...... for chromium species removal from ...
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Development of Nano-Hydroxyapatite Embedded Gelatin Biocomposite for Effective Cr(VI) Removal Venkatrajan Gopalakannan, and Natrayasamy Viswanathan Ind. Eng. Chem. Res., Just Accepted Manuscript • DOI: 10.1021/acs.iecr.5b01224 • Publication Date (Web): 22 Nov 2015 Downloaded from http://pubs.acs.org on November 28, 2015

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Development of Nano-Hydroxyapatite Embedded Gelatin Biocomposite for Effective

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Cr(VI) Removal

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Venkatrajan Gopalakannana, Natrayasamy Viswanathanb*

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a

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009, Tamilnadu, India

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b

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Dindigul – 624 622, Tamilnadu, India.

Department of Chemistry, Velammal College of Engineering and Technology, Madurai - 625

Department of Chemistry, Anna University, University College of Engineering - Dindigul,

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*

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E-mail address: [email protected] (N. Viswanathan)

Corresponding author. Tel.: +91-451-2554066 (O); fax: +91-451-2554066.

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ABSTRACT

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A biocompatible sorbent namely nano-hydroxyapatite embedded gelatin (n-HApGel)

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composite was developed by in-situ precipitation method. The synthesized biocomposite was

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subjected to the removal of hexavalent chromium from aqueous solution in batch mode. The

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FTIR, SEM and EDAX techniques were adapted for investigating the functional groups, surface

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morphology and elements present in the sorbent. The crystalline nature of the composite was

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carried out using XRD studies. TGA analysis gives the thermal stability of the composite. The

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size and shape of the composite was studied using TEM analysis. The sorption process was

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optimized by various influencing factors viz., contact time, adsorbent dosage, temperature, pH

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and competing ions for maximum sorption. The equilibrium data was fitted to Freundlich,

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Langmuir and Dubinin – Radushkevich (D-R) isotherms. Thermodynamic parameters indicate

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the nature of Cr(VI) sorption and a possible sorption mechanism was proposed for the removal

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of Cr(VI) using n-HApGel biocomposite. The suitability of the biocomposite at field conditions

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was tested with field water taken in a nearby industrial area.

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Keywords: Nano-hydroxyapatite; Gelatin; Biocomposite; Hexavalent chromium; Isotherms

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1. INTRODUCTION

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The heavy metals enter into the environment by both natural and anthropological

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activities. Unlike the organic pollutants, metallic pollutants released into the environment tend to

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persevere indefinitely, circulating and finally accumulating throughout the food chain thus

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posing a serious threat to human beings and animals. Chromium is one such naturally occurring

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element, exists with two different oxidation states viz., Cr(VI) and Cr(III). 1 The non- toxic form

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of chromium i.e., Cr(III) is supposed to be essential in glucose metabolism in mammals2

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whereas, Cr(VI) is toxic to both plant and animal cells.2,3 The World Health Organization

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(WHO) has also proposed 0.05 mg/L as maximum dischargeable limit for Cr(VI) of the

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industrial effluents in the surface water.4 Although the discharge cannot be controlled due to its

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widespread application, the only way to avoid its toxicity is to adopt cleaner technology for its

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efficient removal.

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Numerous methods are available for the removal of heavy metals which includes

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adsorption, ion-exchange, precipitation, reduction and membrane processes.5 Among them,

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adsorption process is more preferable due to its easy operation, selectivity and cost effective.6 A

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wide range of novel sorbents like nano ziroconia,7 silica,8 dolamite,9 activated carbon,10

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hydroxyapatite,11 etc., have been subjected for chromium adsorption studies. Amongst which

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hydroxyapatite (HAp) is one of the most promising materials for chromium removal due to its

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low cost, easy availability and higher adsorption capacity. The main reason for employing n-

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HAp is due to its chemical composition and crystal structure.11 Despite of its advantages, it has

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its own limitations viz., poor strength, low stability and also causes pressure drop at field

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conditions.12 In order to overcome such bottle-necks, recently numerous research works have

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been formulated to synthesize biocomposite by dispersing hydroxyapatite over biopolymers like

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chitosan,13 chitin,14 alginate,15 gelatin,11,16,17etc., which possess an enhanced the adsorption

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capacity.

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The biocomposite materials of organic/inorganic origin were extensively studied due to

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their excellent biocompatibility and biodegradability. Gelatin (Gel) is a polypeptide obtained by

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thermal degradation of collagen, a protein widely present in biological connective tissues.

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Gelation of collagen has been widely used in industrial, food science, pharmaceuticals and

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medical applications.18-21 Gelatin possess many chemical groups which have strong affinity to

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metal ions. Therefore, hydroxyapatite, gelatin and modified gelatin were extensively used for

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adsorption of heavy metals from aqueous solution.22-26

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The present investigation concentrates on the synthesis of biocompatible n-HApGel

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composite and subjected to Cr(VI) adsorption by batch process. The instrumental techniques

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like FTIR, TEM, SEM with EDAX, TGA and XRD studies were adapted to characterize the

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synthesized biocomposite. For optimizing maximum sorption capacity (SC), influence of

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contact time, pH and in the presence of other competing ions on chromium adsorption were

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studied. Various adsorption isotherms viz., Freundlich, Langmuir, and Dubinin – Radushkevich

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were formulated. To know the nature of the sorption, thermodynamic parameters were

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calculated and the possible mechanism for the sorption of Cr(VI) onto n-HApGel composite was

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proposed. The suitability of the composite at field conditions was also tested.

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2. EXPERIMENTAL

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2.1. Materials

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Gelatin, potassium dichromate, calcium nitrate, 1,5- diphehylcarbazide, ammonium

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hydroxide, ammonium phosphate and all other reagents used are of AR grade purchased from

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Merck (Germany). The synthetic solutions were prepared using double distilled water.

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2.2. Synthesis of n-HApGel Biocomposite n-HApGel biocomposite was prepared by in situ precipitation method. About 7 g of

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gelatin was added to 100 ml of ammonium dihydrogen phosphate solution and the contents were

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stirred constantly using a magnetic stirrer. When the solution attained homogeneity 5 % of

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calcium nitrate solution was added drop wise with constant stirring for 30 min. After 30 min,

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ammonium hydroxide solution was added in drops to the above mixture followed by vigorous

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stirring. The addition was done until the pH of the solution reached 8 wherein a white slurry of

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n-HApGel composite starts to deposit. The contents were then kept aside for 48 h and after that

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it was filtered and dried in hot air oven. The dried composite was crushed to fine powder using

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ball mill (IKA, Germany). The fine composite powder was sieved to get uniform size and then

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used for chromium sorption studies.

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2.3. Sorption Experiments

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Chromium sorption tendency of the synthesized biocomposite was studied by adapting

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batch mode. During these studies, initial Cr(VI) concentration was fixed at 100 mg/L. Cr(VI)

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solution (100 mg/L) was prepared by dissolving 0.2828g of AR grade potassium dichromate in

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1000 mL distilled water. About 50 mL of this solution was taken in a flask and 0.1g of sorbent

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material was added. The flask was then kept in a thermostated shaker at 200 rpm and the

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supernatant solution was tested for residual Cr(VI) concentration. Since sorption depends on

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various factors like contact time, pH, presence of competing ions and temperature, influence of

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such factors were studied. The solution pH was adjusted using 0.1 M HCl/NaOH solution.

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Temperature studies were conducted for synthesized n-HApGel biocomposite at three different

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temperatures 30, 40 and 50 °C with different initial Cr(VI) concentration viz., 80, 100, 120 and

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140 mg/L. The dosage of the sorbent, volume of Cr(VI) solution and all other parameters were

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maintained as constant.

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Sorption capacity was calculated by using the mass balance equation

Sorption capacity (SC), q =

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C 0 − Ce V (mg / g ) W

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where C0 and Ce are initial and final concentration of Cr(VI) ions (mg/L), V is the volume of

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Cr(VI) solution taken (mL) and W is the weight of the sorbent used for sorption (g).

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2.4. Analysis

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Sorption experiments were conducted using thermostated shaker (REMI, India).

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Chromium concentration was determined by using UV-Visible spectrophotometer –

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Spectroquant – Pharo 300 (Merck, Germany) at 540 nm. The pH of the medium was measured

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using Thermo Orion Benchtop multiparameter kit (VERSA STAR 92) using pH electrode.

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2.5. Characterisation Studies

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The changes in surface morphology of the sorbent before and after Cr(VI) sorption

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process, was investigated using scanning electron microscope (SEM- VEGA3 TESCAN). Also

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elemental analysis on the surface of the sorbent was carried out using EDAX (Bruker Nano

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GMBH, Germany). To find the functional groups of n-HApGel composite, fourier transform

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infrared spectroscopy (JASCO-60 plus) was adopted and the spectrum was recorded between

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the range 400 – 4000 cm-1. For phase identification of the nano composite, X-ray diffraction

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studies was carried out by using XRD-X’per PRO model-PANalytical instrument. Further the

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synthesized composite was subjected to TGA(SDT Q600 V20.9 Build 20 model) to explore the

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phase transitions. The size and shape of sorbents were measured by Transition Electron

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Microscope (TEM) images. TEM images were recorded using TEM CM 200 (PHILIPS) model.

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To investigate the surface area of the sorbent, surface analyser NOVA 1000 model in nitrogen 6 ACS Paragon Plus Environment

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atmosphere was used. pH drift method was followed to determine the pH at zero point charge

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(pHzpc) of the composite.27

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2.6. Computational Analysis

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The Microcal Origin (Version 8) was used for the computational work and to check the

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best of the fit, regression correlation coefficient and chi square analysis (χ2) were used.

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3. RESULTS AND DISCUSSION

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3.1. Characterization Studies

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n-HApGel composite was characterized by various instrumental techniques. Fig. 1

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depicts the FTIR spectrum of gelatin, n-HApGel composite and Cr(VI) sorbed n-HApGel

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composite. In FTIR spectra of gelatin, three characteristic bands at 1641, 1462 and 1242

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cm-1corresponds to amide I, amide II and amide III groups of gelatin respectively.28 In n-HApGel

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composite, bands at 1035 cm-1 and 566 cm-1 might be due to the asymmetric stretching and

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bending modes of PO43- respectively. On the other hand a band at 3411 cm-1 could be due to the

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presence of hydroxyl group, broadening of which reveals the chromium sorption. In the FTIR

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spectra of Cr-loaded n-HApGel composite, shift in almost all the above characteristic bands,

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indicates the sorption of Cr(VI) onto the biocomposite.29

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Fig.1, 2& 3 - Insert here SEM pictures of n-HApGel composite and chromium sorbed n-HApGel composite are

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shown in Fig. 2a and 2b respectively. The first one reveals the well discrete structure of n-

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HApGel composite whereas the latter shows the changes on the surface of n-HApGel composite

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due to chromium sorption. Fig. 2c and 2d depicts the EDAX spectrums of n-HApGel composite

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and chromium sorbed n-HApGel composite. The presence of chromium peak in EDAX spectrum

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of chromium sorbed n-HApGel composite confirms the chromium sorption onto the composite.

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The crystalline nature of the composite was tested by XRD analysis. Fig. 3a shows the

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XRD patterns of n-HAp particles, n-HApGel and Cr-sorbed n- HApGel composites. XRD

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pattern of n-HAp shows peaks at 2θ = 25.92°, 32.1° and 39.81°. These peaks were also found in

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the XRD pattern of n-HApGel biocomposite indicating that, there is no changes in the crystalline

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structure of n-HAp.30 The changes in the XRD pattern of chromium sorbed n-HApGel

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composite suggests the structural changes have occurred after adsorption of Cr(VI) onto the

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sorbent.

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Fig. 3b gives TGA curve of the biocomposite. During thermal analysis, two major weight

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losses were observed. The first weight loss is around 9.8% at 200 - 511o C and second weight

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loss around 13.5% at 720 - 770o C were due to structural decomposition of gelatin and banish of

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carbon dioxide respectively. 31 The specific surface area of synthesized n-HAp particles and

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n-HApGel composite were analyzed under nitrogen atmosphere and found to be 102 and 130

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m2/g respectively.

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The size and shape of sorbent was measured by TEM and given in Fig. 4. The particles of

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n-HApGel composite possess cylindrical rod like shape with homogeneous microstructure and

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tend to agglomerate to form a uniform nano material. Fig.4, 5 & 6- Insert here

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3.2. Effect of Contact Time To quantify the variability of the synthesized n-HApGel composite on contact time with

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the Cr(VI) solution, about 0.1 g of the adsorbent was added in a flask containing 50 mL of 100

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mg/L Cr(VI) solution and the contact time was varied between 10 to 100 min. The effect of

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contact time on SC of n-HAp and n-HApGel composite are shown in Fig. 5a. From the figure it

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is clear that n-HApGel composite attains equilibrium at 80 min, whereas n-HAp attains at 50

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min. The SCs of n-HAp and n-HApGel composite were found to be 10.24 and 17.40 mg/g

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respectively. Since n-HApGel composite possess high SC, it is considered for further

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investigation and its contact time was fixed as 80 min.

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Along with chromium analysis, filtrate is also analyzed for other ions like hydroxide,

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phosphate, calcium, etc. From the analysis it is evident that the filtrate contains hydroxide ion

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that is due to leaching of OH- ions from the sorbent material.

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3.3. Effect of Dosage

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Adsorption process always depends on the dosage of the sorbent in the medium. To

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optimize n-HApGel composite dosage, the sorption experiments were carried out by varying the

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dosage of n-HApGel composite between 0.05 to 0.150 g with 100 mgL-1initial chromium

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concentration and maintaining all other parameters constant. From Fig. 5b, it can be inferred that

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sorption capacity of the sorbent increases with increase in dosage of n-HApGel composite. This

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could be due to, increase in the availability of the reactive sites. After 0.1 g dosage of the

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composite material, SC does not exhibit any remarkable increase, which may be due to the

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saturation during sorption process and this particular 0.1 g dosage will be sufficient for the

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maximum sorption of chromium onto the composite.32-34 Hence the optimum dosage of the

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sorbent was fixed as 0.1 g and the same was maintained for further investigations.

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3.4. Influence of pH

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The pH of the medium plays an important role on the sorption process. To explore the

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influence of pH on the removal of Cr(VI) by the synthesized n-HApGel composite, sorption

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experiments were conducted over the pH range between 3 to11. The pH of the medium was

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adjusted by using 0.1 M HCl/NaOH solution. About 0.1g of the composite was added to 50 mL

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of Cr (VI) solution with 100 mg/L as initial chromium concentration and maintaining all other

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parameters as constant. From the results depicted in Fig. 6a, it is coherent that maximum Cr(VI)

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removal was obtained in acidic pH rather in basic pH. The SC tends to decrease with increasing

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pH level. It is important to remember that Cr(VI) can exists in various forms in different pH

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levels that includes Cr2O72- , HCrO4¯, CrO42-, HCr2O7¯ and H2Cr2O7. When the pH of the

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medium is between 2-6 the predominant species will be Cr2O72- and HCrO4¯ and under this

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acidic pH range, adsorbent will be more protonated facilitating the sorption of negatively

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charged Cr(VI) ions. 35 In addition to this, -NH group present in the polymeric matrix may also

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get protonated and it electrostatically attracts the anionic HCrO4¯ ions. Further Cr(VI) species

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may also get reduced to Cr(III) by its interaction with atoms like nitrogen and oxygen present in

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n-HApGel composite.16, 17, 36 This is due to the fact that Cr(VI) gets reduced in the presence of

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electron donor atoms like nitrogen and oxygen.37, 38 On the other hand, if the pH of the medium

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crosses 6 the most prevailing species of Cr(VI) is Cr2O72-. At this higher basic pH range,

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hydroxyl ion present in the solution competitively binds in the active centers of the sorbent and

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leads to decrease in the SC, as a result sorbent offers a repulsive force towards the chromate

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anion. Therefore, pH of the medium influences the SC of n-HApGel composite i.e., SC is higher

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at acidic pH rather than basic pH. The equilibrium pH of the solution was found to be neutral in

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all the pH ranges.

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The pHzpc study of the materials was carried out by pH drift method and is shown in Fig.

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6b. The pHzpc of n-HAp was found to be 7.70 and it was shifted to 6.62 for the synthesized n-

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HApGel composite. The presence of lower SC in alkaline medium can be elucidated by the fact

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that above pH 6.62 (pHzpc value), the sorbent surface acquires negative charge in alkaline pH and

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hence there is repulsion between the negatively charged composite surface and chromate ion.

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3.5. Influence of Competing Ions

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The normal water contains Ca2+, Mg2+, Na+, Cl−, NO3¯, HCO3¯ and SO42− and the

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influence of these competing ions towards Cr(VI) sorption on n-HApGel composite was studied.

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The sorption experiments were carried out at solution pH of 4.62, with initial concentration of

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competing ions as 200 mg/L, 100 mg/L initial Cr(VI) concentration and by maintain all other

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parameters as constant. Fig. 7 depicts the influence of competing ions on SC of the composite. It

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is clear from the figure that HCO3¯ and SO42− have commendable influence on the SC, whereas

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other ions do not have remarkable influence. This may be due to the similarity in size of HCO3¯

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and SO42− ions with HCrO4¯ ions, which may compete with the active sites of the composite.

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3.6. Sorption Isotherms To establish equilibrium between adsorbed Cr(VI) ions onto n-HApGel composite (qe)

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and unabsorbed Cr(VI) in the solution (Ce), three isotherms namely Freundlich,39 Langmuir40

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and Dubinin-Redushkevich 41were adopted. In such investigations, initial Cr(VI) ion

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concentration was varied as 80, 100, 120 and 140 mg/L at various temperatures like 30, 40 and

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50 °C.

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Table 1 - Insert here The linear plot of log qe vs. log Ce of the composite indicates the applicability of

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Freundlich isotherm and the results were listed in Table 1 . The constructive conditions for

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adsorption was revealed from adsorption intensity i.e., 1/n values, which lie between 0 and l and

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that of n values between 1and 10. Increase in adsorption capacity kF along with temperature

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suggests the endothermic nature of the sorption process. Similarly, applicability of this isotherm

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was further established from higher r values.

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Langmuir adsorption isotherm illustrates the ideal adsorption and administers monolayer

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homogeneous adsorption. The slope and intercept of the plot between Ce/qe vs. Ce gives the

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values of Qo and b respectively. From Table 1 it is apparent that increase in Qo and b values

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indicates the endothermic nature of the sorption process. For different temperatures RL values

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were calculated and also listed in Table 1. These values lie between 0 and 1 explicating the

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favorable condition for the sorption process. Similarly higher r values indicate the applicability

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of Langmuir isotherm.

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Dubinin - Radushkevich isotherm was used to determine the type of adsorption for the

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removal of metal ion from aqueous solution by adsorption. The values of the adsorption capacity

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Xm (mg/g), ε is Polanyi potential and k (mol2/kJ2) the constant related to adsorption energy were

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listed in Table 1. The values of k and Xm were computed from the slope and intercept of the plot

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ln qevs ε2. The higher values of r validate the applicability of D-R isotherm. The values of the

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Polanyi potential, ε lies between 1 and 8 indicating that sorption follows mainly electrostatic

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attraction.

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Among the isotherms, to spot the best fit isotherm model for the sorption of Cr(VI) onto

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n-HApGel composite, chi-square analysis was used and is given in Table 1. It is evident that by

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comparing all the chi square values, Langmuir isotherm possesses low chi square values. So the

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best fit isotherm model for the sorption of Cr(VI) on n-HApGel composite is Langmuir isotherm.

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A comparison of SC of various adsorbents reported in the literature with n-HApGel

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biocomposite has been listed in Table 2.

272 Table 2 & 3 - Insert here 273 274

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3.7. Thermodynamic Behavior and Mechanism of Sorption Process

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The various thermodynamic parameters like ∆H°, ∆S° and ∆G° were calculated to

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understand the nature of sorption. Table 3 shows the values of ∆Hº and ∆Sº which were attained

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from the slope and intercept of the plot of lnKo against 1/T. The spontaneous nature of Cr(VI)

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sorption onto the n-HApGel biocomposite can be revealed from the negative values of ∆G°. The

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positive value of ∆Hº stipulates that the sorption process was endothermic. Throughout the

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Cr(VI) sorption process, randomness between solid-solution interface increases which is evident

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from the positive value of ∆Sº.

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The possible mechanism of chromium sorption onto n-HApGel biocomposite was

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depicted in Fig. 8. The removal of Cr(VI) on the biocomposite was governed by electrostatic

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attraction, ion exchange and reduction. The cation (Ca2+) present in the biocomposite

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electrostatically attracts the negatively charged chromate ions. In addition to this electron

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donating atoms like nitrogen and oxygen present in the sorbent reduces Cr(VI) into less toxic

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Cr(III). Further the hydroxyl ion present in the biocomposite may also get exchanged with the

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negatively charged HCrO4¯ ions from the aqueous solution.

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Table 4 &Fig. 8 - Insert here 3.8. Application of synthesized biocomposite at field conditions The efficiency of the synthesized n-HApGel composite at field conditions was tested by

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collecting field water sample taken in a nearby industrial area. About 0.1 g of the composite was

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added to 50 mL of the field water sample and the contents were shaken for a fixed time at room

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temperature by maintaining all other parameters as constant. The results obtained are presented

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in Table 4. The results showed that there was a significant reduction in Cr(VI) concentration. It is

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evident from the results that the composite may be effectively employed for removing Cr(VI)

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ions from water.

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4.Conclusions

300

The biocomposite n-HApGel was synthesized and successfully removes Cr(VI) ions from

301

aqueous medium by showing enhanced SC than n-HAp particles. n-HApGel biocompatible

302

nano-composite was characterized using various instrumental techniques viz., FTIR, TEM,

303

XRD, TGA, SEM and EDAX analysis. The sorption process was influenced by pH, the

304

maximum sorption was recorded at acidic pH rather in basic. The presence of competing ions,

305

like HCO3¯ and SO42- decreases the sorption capacity of n-HApGel biocomposite. The

306

observation of various thermodynamic parameters indicates that the sorption process is

307

endothermic and spontaneous. The sorption of Cr(VI) onto the n-HApGel biocomposite follows

308

Langmuir isotherm and the mechanism of sorption was mainly due to electrostatic attraction

309

coupled reduction and ion exchange.

310 311 312 313 314 315 316 317 318 319

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FIGURE CAPTIONS Fig.1. FTIR Spectra of Gelatin, n-HApGel Composite and Cr(VI) Sorbed n-HApGel Composite Fig.2. SEM Images of (a) n-HApGel Composite and (b) Cr(VI) Sorbed n-HApGel Composite, EDAX Spectra of (c) n-HApGel Composite and (d) Cr(VI) Sorbed n-HApGel Composite. Fig.3. (a) XRD Pattern of n-HAp Particles, n-HApGel Composite and Chromium Sorbed n-HApGel Composite (b) TGA Curve of n-HApGel Composite. Fig.4. TEM Images of n-HApGel Composite @ a) 100 nm and b) 50 nm Fig.5. (a) Effect of Contact Time on the SC of n-HApGel Composite. (b) Effect of Dosage on the SC of n-HApGel Composite. Fig.6. (a) Influence of pH (b) pHzpc Study Fig.7. Influence of Competing ions on the SC of n-HApGel Composite. Fig.8. Possible Mechanism of Cr(VI) Removal by n-HApGel Composite.

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Table 1 Isothermal Studies of Cr(VI) Sorption onto n-HApGel Composite

Isotherms

Freundlich

Langmuir

30 °C

40 °C

50 °C

1/n

0.773

0.600

0.597

n

1.2936

1.6663

1.6758

kF (mg/g) (L/mg)1/n

12.714

13.856

14.204

r

0.9482

0.9715

0.9715

sd

0.0048

0.0028

0.0028

χ2

0.0010

0.0005

0.0006

Qo(mg/g)

18.828

19.001

19.120

b (L/g)

0.2326

0.2732

0.3088

RL

0.2118

0.1862

0.1683

r

0.9999

1.0000

1.0000

sd

0.0184

0.0084

0.0119

0.0003

0.0002

0.0001

kDR(mol /J )

2.2013E-08

1.8211E-08

1.4473E-08

Xm(mg/g)

6.7376

6.8007

6.8927

ε (kJ/mol)

4.7659

5.2399

5.8776

r

0.9818

0.9709

0.9775

sd

0.0055

0.0065

0.0050

χ2

17.9349

18.3901

18.6838

χ

2 2 2

Dubnin-Radushkevich

Temperature

Parameters

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Table 2 Comparison of Adsorption Capacities of Various Adsorbents towards Cr(VI) Removal. Adsorption capacity (mg/g)

Reference

n-HApGel composite

17.40

Present study

CTAB-Silica Gelatin composite

16.60

17

Gelatin-Yeast

500.00

26

Bituminous activated carbon

10.53

42

Dolochar

2.10

43

Modified montmorillonite

11.97

44

Silica gel/chitosan composite

3.50

45

Cerium cross linked magnetic alginate beads

14.29

46

n-HAp/Chitosan composite

3.40

47

n-HAp/Chitin composite

2.80

47

Magnetite

10.60

48

Montmorillonite/magnetite nano particles

15.30

48

Nano Silica-Aspergillus ustus

526.3

49

Nano Silica -Fusarium verticillioides

416.7

49

Nano Silica -Pencillium funiculosum

243.9

49

Gelatin-Grafted Yeast biosorbent

1000

50

Activated carbonC-Fe3O4

588.24

51

Activated carbon-Fe3O4-Yeast

769.23

51

Adsorbent

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Table 3 Thermodynamic Parameters of Cr(VI) Sorption onto n-HApGel Composite Thermodynamic Parameters

Temperature

∆G˚ (kJ mol-1)

30 °C

-3.40

40 °C

-3.47

50 °C

-3.55

∆H˚ (kJ mol-1)

1.18

∆S˚ (kJ K-1 mol-1)

0.01

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Table 4 Application of n-HApGel Biocomposite at Field Conditions

Water quality parameters

Before treatment

After treatment

Chromium(mg/L)

1.07

Nil

pH

7.54

7.41

Cl- (mg/L)

1810

1050

Total Hardness (mg/L)

1100

840

Total Dissolved Solids (mg/L)

4800

1900

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Fig. 1.Gopalakannan and Viswanathan

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a

b

c

d

Fig.2.Gopalakannan and Viswanathan

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Fig.3.Gopalakannan and Viswanathan

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Fig.4. Gopalakannan and Viswanathan 29 ACS Paragon Plus Environment

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Fig.5. Gopalakannan and Viswanathan

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Fig.6.Gopalakannan and Viswanathan 31 ACS Paragon Plus Environment

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Fig. 7.Gopalakannan and Viswanathan

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Fig. 8.Gopalakannan and Viswanathan

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Development of Nano-Hydroxyapatite Embedded Gelatin Biocomposite for Effective Cr(VI) Removal Venkatrajan Gopalakannana, Natrayasamy Viswanathanb* a

Department of Chemistry, Velammal College of Engineering and Technology, Madurai - 625 009, Tamilnadu, India b

Department of Chemistry, Anna University, University College of Engineering - Dindigul, Dindigul – 624 622, Tamilnadu, India. *

Corresponding author. Tel.: +91-451-2554066 (O); fax: +91-451-2554066. E-mail address: [email protected] (N. Viswanathan)

For Table of Contents Only

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