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 CCHHEEMMIICCAALL  EENNGGIINNEEEERRIINNGG  TTRRAANNSSAACCTTIIOONNSS  
 

VOL. 39, 2014 

A publication of 

 
The Italian Association 

of Chemical Engineering 

www.aidic.it/cet 
Guest Editors: Petar Sabev Varbanov, Jiří Jaromír Klemeš, Peng Yen Liew, Jun Yow Yong  

Copyright © 2014, AIDIC Servizi S.r.l., 

ISBN 978-88-95608-30-3; ISSN 2283-9216 DOI: 10.3303/CET1439111 

 

Please cite this article as: Vieira M.G.A., de Almeida Neto A.F., da Silva M.G.C., 2014, Mechanisms of copper and mercury 

adsorption on bentonite clays from EXAFS spectroscopy, Chemical Engineering Transactions, 39, 661-666  

DOI:10.3303/CET1439111 

661 

Mechanisms of Copper and Mercury Adsorption on 

Bentonite Clays from EXAFS Spectroscopy 

Melissa G. A. Vieira*, Ambrósio F. de Almeida Neto, Meuris G. C. da Silva 

University of Campinas, Albert Einstein Av., 500, Cidade Universitária "Zeferino Vaz", Zip Code: 13083-852 Campinas – 

SP - Brazil 

melissagav@feq.unicamp.br 

Copper(II) and Mercury(II) cations are classified as important heavy metal pollutants in industrial 

wastewaters. In this study, Extended X-Ray Absorption Fine Structure (EXAFS) spectroscopy was used to 

provide information about the coordination environment and nearest neighbouring atoms involved in the 

copper(II) and mercury(II) ions adsorption on raw and calcined bentonite clays from Northeast Brazil. 

EXAFS experiments were carried using a channet-cut Si (111) monochromator. All the spectra were 

performed in transmission mode and Cu (8987 eV) K and Hg (12284 eV) L edges were collected. Each 

spectrum corresponded to an average of 3 independent scans. Standard compounds (copper and mercury 

oxides) were used in order to distinguish the bond differences between the heavy metal and coordination 

spheres (O atoms). Based on EXAFS investigation, it is possible to conclude that the structure of heavy 

metal ions on clays does not depend primarily of the calcinations of the structure. The main metal 

interaction observed for copper and mercury ions occurred on hydroxyl groups. 

1. Introduction 

In the last years, environment contamination by heavy metals has gained much attention due to the 

significant impact on the public health. Copper is an ion extremely toxic and used in different industrial 

applications. Several methods are used to remove toxic metals from aqueous solution such as ion 

exchange, reverse osmosis, adsorption (Gimenes et al., 2013), complexation and precipitation (Juang and 

Shao, 2002). Adsorption is considered an effective and economical method for removal of pollutants from 

industrial wastewater at low concentration (Ng et al., 2002). 

The bentonite clay is composed by unit cells made up of two silica tetrahedral sheets with a central 

alumina octahedral sheet. This material has been described as a promising adsorbent for removal of 

heavy metals such as copper (Almeida Neto et al., 2013; 2012), cadmium and lead (Galindo et al., 2013) 

and nickel (Vieira et al., 2010 a, b). Most of the studies on heavy metal adsorption have been dedicated to 

the determination of the overall uptake performance; however, there is limited information available on 

identifying adsorption mechanism. 

Analytical techniques, such as XPS (Dambies et al., 2001), Mösbauer spectrometry (Bhatia and Ravi, 

2000), XANES and EXAFS (Gardea-Torresdey et al., 2002), can be used to identify surface groups that 

are primarily responsible for binding metallic species and the state of adsorbed metals. Extended X-ray 

absorption fine structure spectroscopy (EXAFS) provides information about the coordination structure, like 

the number of atoms in the neighbourhood of a determined coordination sphere (-OH), and the bond 

distance between heavy metal and site. This technique presents several important advantages in studying 

local structures, since is sensitive only to the short-range order and can show the structure of both 

crystalline and non-crystalline samples.  

EXAFS is sensitive to the local structure around specific species of interest, such heavy metals ions. 

Because of this, it is possible to use this technique to directly measure partial pair correlation functions, 

around the targeted atoms in solution with a relatively small number of structural variables (Gardea-

Torresdey et al., 2002). This interaction creates a wave function that can be Fourier transformed to give a 

pseudo-radial distribution function. In this analysis the major peak observed in the Fourier transform is the 



 
662 

 
interatomic distance between target metal and coordination sphere, in this case between heavy metal 

(copper or mercury) and functional groups of clays. 

In this paper, Extended X-Ray Absorption Fine Structure (EXAFS) spectroscopy was used to provide 

information about the coordination environment and nearest neighbouring atoms involved in the heavy 

metal ion adsorption on bentonite (Bofe and Verde-lodo) clays. Copper and mercury ions were studied due 

to their toxicity, which, depends mainly of theirs oxidation states and concentration. This approach 

provides with valuable insight for explaining the adsorption mechanism exhibited by these heavy metal 

ions on clays. 

2. Experimental 

2.1 Materials 
The bentonite Bofe and Verde-lodo clays, from the northeast of Brazil, were used in this study. The 

adsorption experiments were performed on raw and calcined clays. Bofe and Verde-lodo clay were 

calcined at 773 K for 24 h in order to improve metal adsorption properties. 

2.2 Metal Adsorption 

Equilibrium tests were performed with different concentrations of adsorbate and temperatures. For 

maintaining pH of the medium, solutions of NH4(OH) with concentrations of 0.01 mol/L HNO3 or 0.01 mol/L 

were added in order to adjust the pH value. The pH was monitored before and after adsorption. Cu(II) and 

Hg(II) were removed at pH 4.5 for 60 h at 25 °C. The Cu (II) and Hg (II) solutions were prepared using 

copper nitrate and mercuric acetate, respectively. Diagrams of copper and mercury species distribution as 

function of pH for Cu
2+

 and Hg
2+

 ions were simulated using Hydra (Hydrochemical Equilibrium-Constant 

Database) software (Puigdomenech, 2004).  

2.3 EXAFS experiments 
EXAFS experiments were performed with saturated samples in the highest concentrations of equilibrium 

tests and carried out at Brazilian National Synchrotron Light Laboratory (LNLS), using a channel-cut Si 

(111) monochromator. All the spectra were performed in transmission mode and were collected around Cu 

(8,987 eV) K and Hg (12,284 eV) L edges. Each spectrum corresponded to an average of three 

independent scans. Standard compounds (copper oxide and mercuric oxide) were used in order to 

distinguish the bond differences between the heavy metal and coordination spheres (O atoms).  

2.4 Analysis of EXAFS data 
The kinetic energy of the photoelectrons ejected from the clay samples and standard compound was 

calculated based on the edge position of the metal of interest (8,987 and 12,284 eV, for Cu and Hg) and 

converted to the vector (k) space. This provide an EXAFS curve, which depends on the module of the 

wave vector (reciprocal space), then Fourier transformed to radial coordinates and converted into 

interatomic distance space (real space). These data directly reflect the average local environment around 

the absorption atoms. Afterwards, it approaches to the distribution of neighbouring atoms around the 

adsorbed central atom, where each peak obtained corresponds to a coordination sphere. First, for the 

treatment of EXAFS data, it was necessary analyse a standard compound, whose structural parameters 

were already known. All EXAFS data were analyzed using ATHENA
®
 software (IFEFFIT package). This 

computational program could perform all transformations described before. 

3. Results and Discussion 

3.1 Effect of pH  
The distribution of copper and mercury species as a function of pH for concentration of metal adsorption 

was simulated using Hydra software, as shown in the Figure 1. It is observed that, for the study range of 

pH, the dominant specie is Cu
2+

 for values up to 5.0. The increment of pH in this range reducesCu
2+

 

concentration while increases the CuO concentration. This fact indicates that adsorption occurs for pH < 

5.0 the Cu
2+

, since there is no chemical precipitation of this metal. 



 
663 

 

Figure 1: Metal speciation for (A) 100 mg/L Cu and (B) 50 mg/L Hg 

0,0 0,2 0,4 0,6 0,8 1,0 1,2 1,4

0,00

0,05

0,10

0,15

0,20

A

 

 

q
* 

(m
m

o
l/
g

)

C (mmol/L)

 Bofe raw

 Bofe calcined

 Langmuir model

 Freundlich model

0,0 0,2 0,4 0,6 0,8 1,0 1,2 1,4 1,6

0,00

0,05

0,10

0,15

0,20

0,25

0,30

B

 

 

q
* 

(m
m

o
l/
g
)

C (mmol/L)

 Verde raw

 Verde calcined

 Langmuir model

 Freundlich model

 

Figure 2: Plots of q* vs. C for Cu(II) ions uptake on: (A) Bofe raw and calcined clay; (B) Verde-lodo raw 

and calcined clay (Experimental conditions: clay 1 g/L, pH 5.7, time 360 min, temperature 298 K) 

3.2 Copper and Mercury Adsorption 
The isotherm plots of the ion´s concentration on the solid phase, q*, vs. concentration of the ion on the 

liquid phase, C, at 298 K were given in Figure 2. It is observed that, for any equilibrium concentration of 

Cu(II) ions, the Bofe and Verde-lodo raw clays presented much higher uptake of Cu(II) ions than Bofe and 

Verde-lodo calcined clays. 

The Langmuir and Freundlich plots (Figure 2) were obtained from Eqs(1) and (2), respectively: 

bC

bCq
q

m




1
*  (1) 

n
Caq )(*   (2) 

The parameters obtained for non-linear curve fit are shown in Table 1. 

The Langmuir monolayer capacity, qm, has values of 0.06 to 0.29 mmol/g (Table 1). Calcination has 

negative influence on the monolayer capacity of both clays. The qm values follow the same increment 

order as the Freundlich adsorption capacity, i.e. Bofe raw < Verde raw. This result is in conformity with the 

order of adsorption capacity of the four clay adsorbents. 

The adsorption of mercury showed low values of removal amount. The EXAFS analysis for mercury 

adsorbed were performed by transmittance and spectrum obtained in the XANES region due to low 

amount of this metal 

 

 



 
664 

 
Table 1: Langmuir and Freundlich coefficients for adsorption of Cu(II) ions on clays 

System Langmuir Freundlich 

qm (mmol/g) b (L/g) R
2
 a n R

2
 

Cu/Bofe raw 0.1540 25.3234 0.9585 0.1639 0.2582 0.9553 

Cu/Bofe calcined 0.0748 16.7868 0.9725 0.0752 0.3015 0.9259 

Cu/Verde raw 0.2926 5.0544 0.9649 0.2455 0.3769 0.9914 

Cu/Verde calcined 0.0599 18.1980 0.9288 0.0611 0.3009 0.9378 

 

   

    

Figure 3: Radial structure function of the copper ions adsorption on (A) Bofe raw, (B) Bofe calcined, (C) 

Verde-lodo raw and (D) Verde-lodo calcined clays 

3.3 Copper-Clay Complex 

The EXAFS spectra of the copper adsorption are shown in Figure 3 (Fourier transforms, real space). The 

Cu K-edge EXAFS spectra were taken up to 8,987 eV. 

Each peak in the absorption spectra represents one coordination sphere and its distance to the target 

atom. There are three stronger peaks located at 1.80 Å approximately in the FT curve for CuO, where the 

first one arises from an oxygen shell (Cu-O), while the second one comes from a Cu type shell (Cu-Cu), 

and the third one arising from Cu-O-Cu bond. For copper hydroxide, a stronger peak at 1.5 Å was 

observed, corresponding to Cu-O bond (Collins et al., 1999). 

A strong peak was observed, in all the cases, at approximately 1.5 Å (first metal coordinate sphere), that 

corresponds to the backscattering oxygen atoms of the first shell.   

The EXAFS spectrum of the copper(II) treated clays (Figure 3) consist in an octahedral oxygen shell with 

Jahn–Teller distortion. The equatorial Cu–O bond is 1.93 Å whereas the two axial Cu–O bond lengths are 

2.12, 2.39, 2.72 and 2.64 Å. After adding a Cu–P distance of 2.98 Å, there was a significant improvement 

of the fit parameters forcalcined Bofe clay. However, at natural pH of contact solid-fluid, the main 

precipitation product on the clay surfaces seems to be copper(I) oxide. The EXAFS spectra recorded at pH 

4.5 are almost identical, showing that the speciation is the same at all samples. 

3.4 Mercury-Clay Complex 
The fit of the experimental EXAFS data and the corresponding FTs at pH 4.5 for mercury(II) sample are 

given in Figure 4. For comparison purposes XANES spectrum of the mercury(II) oxide [HgO] that has a 



 
665 

chain structure with the bonds to the water molecules very tightly bound in linear fashion and four weak 

bonds to oxygen, as shown in Figure 4. The mercury(II) oxide spectrum is similar to the mercury(II) 

adsorbed clay at pH 4.5. Only one shell of light back-scattered around mercury at short bond distance, 

≈1.65 Å, is observed in the FT, Figure 4. This shows that mercury(II) at this pH binds to oxygen in a linear 

fashion as previously found for adsorbed mercury(II) ion on goethite surfaces (Collins at al., 1999) and in 

solid mercury(II) oxide. It seems very likely that the mercury(II) is sorbed to the clay surface as a hydrolysis 

complex, since hydrated mercury(II) ions easily hydrolyze (pKa ≈ 3.5) depending on temperature and ionic 

strength and a precipitation of HgO does not occur. 

 

    

 

Figure 4: The EXAFS spectra of the mercury ions adsorption on (A) Bofe raw, (B) Bofe calcined, (C) 

Verde-lodo raw and (D) Verde-lodo calcined 

The most relevant contribution to the EXAFS region of montmorillonite was recognized to Hg surrounded 

by six oxygen atoms. Two oxygen atoms are closer to Hg, at distances of 1.66, 1.91, 1.62 and 1.59 Å, 

respectively for Bofe raw, Bofe calcined, Verde-lodo raw and Verde-lodo calcined clays. The distance from 

Hg of the three remaining oxygen atoms is greater and reaches 2.40 Å. The short distances could be 

interpreted as indicators of Hg–O bonds in montroydite-like compounds, whereas the long distances can 

be attributed to Hg–O bonds in Hg–HO complexes. This hypothesis was also formulated by Collins et al. 

(1999) in studies of a goethite substrate. The lack of symmetry in the Hg coordination sphere is consistent 

with the two-steps release of the mercury at high temperatures (Brigatti et al. 2005). The EXAFS analysis 

also refines two Hg atoms at 3.17, 3.10 and 3.44 Å, from the central Hg atom, for Bofe calcined, Verde-

lodo raw and Verde-lodo calcined, respectively. 

4. Conclusion 

Based on EXAFS investigation, it is possible to conclude that the structure of heavy metal ions (copper) on 

clay adsorbents does not depend primarily of calcinations in the structure. For copper ions on natural clay 

it was not possible to observe the occurrence of metal interaction mainly on hydroxyl groups. The FT 

functions generated from the Hg L-edge EXAFS spectra of Hg-rich Bofe and Verde-lodo, raw and calcined 

showed a good match in the peak positions and intensities of the experimental spectra for all the samples, 

compared with HgO (montroydite) as a model compound. For mercury and copper it was not possible to 



 
666 

 
distinguish if the interaction took place preferentially on hydroxyl groups, being necessary the utilization of 

this technique with others like FTIR and XPS together. 

Acknowledgements  

The authors thank FAPESP and CNPq for financial support and Brazilian National Synchrotron Light 

Laboratory (LNLS) for EXAFS analyses. 

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