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CHEMICAL ENGINEERINGTRANSACTIONS 
 

VOL. 60, 2017 

A publication of 

 

The Italian Association 
of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Luca Di Palma, Elisabetta Petrucci, Marco Stoller
Copyright © 2017, AIDIC Servizi S.r.l. 
ISBN978-88-95608- 50-1; ISSN 2283-9216 

Adsorption of Humic Acid from Aqueous Solution  on Different 
Modified Bentonites 

Nabil Bougdaha*,Nabil Messikha,Salim Bousbaa,Pierre Magrib,Fayçal Djazia,c, 
Rachida Zaghdoudic 

a
 Département de Pétrochimie et Génie des Procédés, Faculté de Technologie, Université 20 Août 1955-Skikda, BP 26 

Route d’El-Hadayek, Skikda 21000, Algérie.   
b
 LCP-A2MC, Université de Lorraine, 1, bd Arago-57078 METZ, Cedex 3, France         

c
 Laboratoire LRPCSI, Université du 20 Août 1955, B.P 26 Skikda 21000, Algérie.  

 

bougdah_nabil@yahoo.fr 

The main objective of this work is the preparation and the characterization of a modified bentonites based 
adsorbents by intercalation with DMSO and DMF. Modified bentonites were analyzed using thermal analysis 
(TGA), infra-red analysis (FTIR) and X-ray diffraction. The X-ray results indicate that the geometry of the 
interlayer space was modified for all bentonites, and the interlayer distances observed are in the order of 1 to 
1.41 nm. The adsorption ability and efficiency of different bentonites was tested for the removal of humic acid 
HA in aqueous solutions. In fact, batch adsorption experiments were carried out under different conditions 
including the adsorbent dose, the contact time, the initial humic acid concentration, the solution pH, in order to 
investigate their effects on the retention capacity of the modified bentonites.  The maximum adsorption 
capacity of HA was found to be 16.97 mg/g, 14.65 mg/g, and 11.2 mg/g for DMF-bentonite, DMSO-bentonite 
and bentonite respectively. In conclusion Modified bentonites showed quite good capabilities in removing HA 
from aqueous solutions.  
 
1. Introduction  
Humic acid (HA) is one of the major components of humic substances which arise from the microbial 
degradation of biomolecules, and it is ubiquitous in surface water and ground water. The existence of HA in 
drinking water can lead to colour, taste and odour problems, and to biological instability of drinking water in 
distribution system. Furthermore, HA can bind various pollutants including toxic heavy metals and synthetic 
organic chemicals, and carry them through water treatment facilities and distribution systems. The adsorption 
remains one of the most effective methods to remove humic acid from water. 
This work focuses on the preparation and characterization from modified bentonite by DMSO and DMF. The 
resulting adsorbent is tested humic acid removal from water and adopted the optimal parameters to remove 
humic acid. 
 
2. Materials and methods 

2.1. Preparation of organo-clay  

The Na-exchanged form of the bentonite was prepared by stirring 1 M NaCl solution containing a sample of 
the clay for 24 hours at ambient temperature. Next, the solution was filtered and the clay was washed with 
distilled water to remove NaCl and other exchangeable cations from the clay. Rinsing was repeated until the 
negative reaction on Cl- ions in filtrate was obtained (test with 0.1 M AgNO3) then dried at 70°C (Safa Ozcan 
2004). The Na-bentonite was intercalated of DMSO or DMF into bentonite was done in a following way: 20 
grams of bentonite was stirred with 200 ml of anhydrous DMSO or DMF for 9 days at 70°C. The filtered clay 
was washed with 25 ml of dioxane and 25 ml of ethanol, and then dried at 110°C ( J. Tunney 1996, R.L. Frost 
1999). 
 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1760038

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Bougdah N., Messikh N., Bousba S., Magri P., Djazi F., Zaghdoudi R., 2017, Adsorption of humic acid from aqueous 
solution on different modified bentonites, Chemical Engineering Transactions, 60, 223-228  DOI: 10.3303/CET1760038 

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2.2. Characterization of modified clays  

Modified bentonites were analyzed using thermal analysis (TGA), modifications of clays were confirmed by 
FTIR spectra obtained a spectrophotometer (Spectrum One FTIR spectrometer of Perkin Elmer) and 
Structural modifications of clays were characterised by X-ray powder diffraction (XRD).  

3. Results and discussion 
3.1. Thermogravimetric analyses 

Thermal modification of bentonite, DMSO-bentonite and DMF-bentonite are illustrated by curves given in fig.1. 
The TGA record of the bentonite is show in fig.1.a. The mass loss of 8.7% observed at the mean temperature 
of 80.7°C corresponds to the dehydration of the clay.  
In the case of the TGA of DMSO-bentonite, fig.1.b, the two stages reaction was observed. The first mass loss 
of 1.9% corresponding to the release of the adsorbed water was followed by the second one of 6.2% observed 
at 207.06°C. 6.2% of evaporated DMSO corresponds to the solvent adsorbed/absorbed by the clay. 
The more complex TGA thermal curve, fig.1.c, was observed with DMF-bentonite. The four stages of the mass 
loss were observed in this case. The water loss was of 1.6% atteined the maximum desorption rate at 52.3°C. 
Two following mass losses occur at 193.9°C (4.0%) and 320.6°C (2.5%), respectively and correspond to 
evaporation of absorbed and chemisorbed DMF. The last one observed at 532.9°C (2.3%) corresponds to 
decomposition of adsorbed species. Consequently the adsorbed and absorbed DMF constituted 8.8% of the 
mass of this organoclay. 

 

                                (a)                                                                                                     (b) 
 

 
(c) 

Figure 1 TGA/DTG analysis of bentonite (a), DMSO-bentonite (b), DMF-bentonite (c). 

3.2. FT-IR analysis 

Figure.2.a displays the typical spectrum of bentonite with the intense band at 982 cm-1 from stretching 
vibration of Si-O, the other bands correspond to the presence of sorbed water in the sample: the υ2 H-O-H 
bending vibration spectral range at 1600-1700 cm-1; υ1 H-bonding to Si-O-Al is located at 3370-3480 cm-1 and 
the Hydrogen bond to Si-O-Si linkage is located at 3613 cm-1.  

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For the DMF-bentonite, the band corresponding to the υOH is drastically reduced proving the insertion of DMF 
in the bentonite structure. The chemical function of the DMF is present in the infrared spectra by assigned the 
well defined band at 1660cm-1 to the υC=O + υC-N vibration. The band at 1387 cm-1 corresponds to the υC-N 
+ δCH3 and the bands between 1400 and 1500 cm-1 is attributed to δCH3.   

 

  

  
 
 
 
 
   (a)   
 

 
 
 
 
 
 
 (b) 
 
 
 
 
 
 
 
 
(c) 

Figure 2 Shows the infrared spectra of bentonite (a), DMSO-bentonite (b) and DMF-bentonite (c). 

3.3. XRD analysis  

The XRD spectra of bentonite, DMSO-bentonite and DMF-bentonite are presented in fig.3 (a), (b) and (c) 
respectively. Accordingly, the d001 reflection occurs at 2-theta= 6.6 for bentonite, 6.3 for DMF-bentonite and 
6.3 for DMSO-bentonite.  
This indicates that that the geometry of the interlayer space was modified. The interlayer distance depends on 
the surface electrical charge and on the arrangement and the nature of molecules filling the interlayer space. 
The interlayer distance observed in the case of bentonite 13.5 A°. Natural bentonite surface is negatively 
charged due to the isomorphous substitutions within the layers of Al

3+ for Si4+ in the tetrahedral sheet and and 
Mg2+ for Al3+ in the octahedral sheet. For modified bentonite the X-ray peak shifted to lower angles indicating 
increasing basal spacing. The interlayer distance observed in the case of DMSO-bentonite and DMF-bentonite 
was of 14.1 A° and 13.9 A° respectively. These polar solvents intercalate bentonite and form probably bilayer 
structure in the interlayer space. The interlayer distance is slightly higher comparing to water bilayer. 

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Figure 3 XRD pattern of bentonite, DMF-bentonite  and DMSO-bentonite. 

3.4. Adsorption kinetics studies 

Kinetic experiments were carried out in erlen-meyer flasks containing saturated aqueous solutions of humic 
acid (100 ml) with 40 mg of the natural bentonite or modified bentonite at 25°C. Solutions were stirred at 300 
rpm during a selected lapse of time. Then, the solution was centrifuged to removing the clay dispersion and 
analysed using the UV-vis spectrometry. The solution concentration allowed to calculating the quantity qt 
(mg/g) of the humic acid adsorb by one gram of adsorbent.  

m

v
CCq et ×−= )( 0                                                                                                                                 (1) 

Where qt is the adsorption capacity of the adsorbent, C0 and Ce (mg/L) are the initial and equilibrium 
concentrations, respectively, of the adsorbate in the solution. V (L) the volume of the solution and m (g) is the 
mass of adsorbent used. This experiment was repeated for laps of time going up to 270 min. 
Fig.4 presents the adsorption kinetics obtained at room temperature with the initial concentration of adsorbate 
being 20 mg/L solutions of humic acid.  

0 50 100 150 200 250 300
0

2

4

6

8

10

12

14

16

18

q
e
 (

m
g

/g
)

t (min)

 bentonite
 DMSO-bentonite
 DMF-bentonite

 

Figure 4. Kinetics of adsorption the humic acid on modified bentonites C0 =20 mg/L. 

Figure 4 shows the variation of the amount of HA adsorbed as function of time onto bentonite and modified 
bentonite. It may be observed from the figure that the amount of HA adsorbed onto bentonite and modified 
bentonite was rapid initially and then slowed down gradually until the equilibrium is reached  about 210 min. 
this is because that a large number of vacant surface sites are available for adsorption during the initial stage, 
adsorption slowed down in later stages because after some time the remaining vacant surface sites are 

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difficult to be occupied due to repulsive forces between the adsorbate molecules in the aqueous solution and 
those on the adsorbent surface (D. Doulia 2009, Jianwei. Lin 2012 and H. Uslu 2009) .    
Humic acid adsorbed by bentonite, DMSO-bentonite and DMF-bentonite reaches 11.2 mg/g, 14.65 mg/g and 
16.97 mg/g respectively.  

3.5. Adsorption isotherms 

An adsorption isotherm describes the mechanism of retention of the solution components to a solid-phase at a 
constant temperature and pH. Batch experiments were conducted by shaking 40 mg of bentonite or modified 
bentonite with 100 ml aqueous solutions of HA at different concentrations (2-50 mg/L) was equilibrated during 
3.5 hours at 25°C  Results obtained for HA are presented at fig. 5a, 5b and 5c respectively. 

0 1 0 2 0 3 0 40
0

5

10

15

20

25

30

q
e
 (

m
g

/g
)

C
e
 (m g /L )

(a )

0 5 1 0 1 5 2 0 25 30 35 40
0

5

1 0

1 5

2 0

2 5

3 0

3 5

q
e
 (

m
g

/g
)

C
e
 (m g /L )

(b )

 

0 5 10 15 20 25 30 35
0

10

20

30

40

50

q
e
 (

m
g

/g
)

C
e
 (m g/L)

(C)

 

Figure 5. Adsorption isotherms of humic acid onto; a) bentonite, b) DMSO-bentonite, C) DMF-bentonite 

The equilibrium adsorption isotherm is one of the most important data to understand the adsorption system 
mechanisms. The adsorption isotherms of HA on bentonite, DMSO-bentonite and DMF-bentonite shown in 
Fig.5. It was shown that the HA adsorption capacity for DMF-bentonite was much higher than that for DMSO-
bentonite and bentonite, indicating that surface modification of DMF-bentonite enhances the HA adsorption 
capacity. Adsorption isotherm showed an initial steep slop and reached a plateau at elevated equilibrium 
conditions, indicating a relatively high affinity type interaction of HA with modified clay surface. Although the 
amounts adsorbed by organo-bentonite increase compared to unmodified bentonite, this increase is not 
regular. The adsorption of HA onto DMF-bentonite, DMSO-bentonite and bentonite has an L-type profile of 
Giles et al’s classification (C. H. Giles).  
 
3.6. The effect of pH on the adsorption of humic acid 
The influence of pH on the adsorption of HA onto bentonite modified was investigated in the pH range 2.3- 9.  
Fig.6 shows the variations in the removal of AH at various solution initial pH. It was observed that the 
maximum quantity removal of HA was at pH 3.2. As the pH of the solution was increased from 2.3 to 9, the 
quantity adsorbed of HA decreased from 46.6 mg/g to 10.87 mg/g for DMF-bentonite, 46.77 mg/g to 3.62 mg/g 
for DMSO-bentonite and 47.07mg/g to 4.05mg/g for bentonite. The maximum adsorption at pH 3.2 this may 
attribute to the HA molecules comes near organic cations on the clay surface the interaction between the 
positive surface and HA molecule is thermodynamically favored and this results in expulsion of an acidic 

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hydrogen from carboxylic acid group of HA molecule to generate a negatively charged HA, the groups –COOH 
of HA dissociated into HA-COO-. 

0 2 4 6 8 10
0

10

20

30

40

50

q
e
(m

g
/g

)

pH

 bentonite
 DMSO-bentonite
 DMF-bentonite

 

Figure 6. Effect of pH on the adsorption of humic acid on modified bentonites. 

4. Conclusion 
The work carried out concerns the adsorption of HA on various clay materials. From this point of view, we 
have developed modified clays in order to improve their adsorption properties.  
The removal of humic acid by bentonite and bentonite modified with DMSO and DMF was carried as a 
function of the influence of various parameters such as contact time, pH of the solution and concentration of 
the adsorbed molecules. Results obtained confirm the utility of modified bentonites to removing humic acid 
from aqueous solutions. The maximum adsorption capacity of HA was found to be 16.97 mg/g, 14.65 mg/g, 
and 11.2 mg/g for DMF-bentonite, DMSO-bentonite and bentonite respectively.  
The results obtained in this work confirm the utility of modified bentonites in removing humic acid from 
aqueous solutions.    
 
References  
Frost R L., Kristof J., Horvath E., Kloprogge J T., 1999. deintercalation of dimethylsulphoxide 

intercalatedkaolinites- a DTA/TGA and Raman spectroscopic study, Thermochimica Acta, 327, 155-166. 
Danae Doulia., Leodopoulos Ch., Gimouhopoulos K., Rigas F., 2009. Adsorption of humic acid on acid-. 

activated Greek bentonite, Journal of Colloid and Interface Science, 340,131–141. 
Bougdah N., Magri P., Modaressi A., Djazi F., Zaghdoudi R., Rogalski M., 2015. Suitable organoclays for . . . 

removing slightly soluble organics from aqueous solutions, Journal of chemical and pharmaceutical 
research, 7(10), 295-306. 

Jianwei Lin., Yanhui Zhan., 2012. adsorption of humic acid from aqueous solution onto unmodified and .      
surfactant-modified chitosan/zeolite composites, 200-202, 202-213.  

Safa Ozcan A., Bilge Erdem., Adnan Ozcan., 2004. Adsorption of acid blue 193 from aqueous solutions onto .  
Na-bentonite and DTMA-bentonite, J colloide and interface science, 280, 44-54. 

Tunney J J., Detellier C., 1996. Aluminosilicate nanocomposite materials polyethylene gjycol-kaolinite. 
intercalates, J. Chem. Mater, 8, 927-935., 155-166. 

Uslu H., 2009. adsorption equilibria of formic acid by weakly basic adsorbent amberlite IRA-67: equilibrium,. 
kinetics, thermodynamic, Chem. Eng. J. 155, 320-325.   

 

 

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