Available online at BCREC Website: http://bcrec.undip.ac.id
Bulletin of Chemical Reaction Engineering & Catalysis, 8 (1), 2013, 61 - 69
Research Article

Preparation and Characterization of Acids and Alkali
Treated Kaolin Clay
Sachin Kumar 1* , Achyut Kumar Panda2, R. K. Singh1
1

2

Department of Chemical Engineering, National Institute of Technology, Rourkela-769008, India

Department of Chemistry, School of Engineering and Technology, Bhubaneswar Campus, Centurion
University of Technology and Management - 752050, India
Received: 1st March 2013; Revised: 9th April 2013; Accepted: 19th April 2013

Abstract
Kaolin was refluxed with HNO3, HCl, H3PO4, CH3COOH, and NaOH of 3 M concentration at 110 °C for 4
hours followed by calcination at 550 °C for 2 hours. The physico-chemical characteristics of resulted leached
clay were studied by X-Ray Fluorescence spectroscopy (XRF), X-Ray Diffraction (XRD), Fourier Transformed Infrared Spectroscopy (FTIR), Thermogravimetric Analysis (TGA), Differential Thermal Analysis
(DTA), Scanning Electron Microscope (SEM), Temperature Programmed Desorption (TPD) ammonia method, and N2 adsorption techniques. XRF and FTIR study indicate that acid treatment under reflux conditions lead to the removal of the octahedral Al 3+ cations along with other impurities. XRD of acid treated
clay shows that, the peak intensity was found to decrease. Extent of leaching of Al 3+ ions is different for different acid/base treatment. The chemical treatment increased the Si/Al ratio, surface area and pore volume
of the clay. Thus, the treated kaolin clay can be used as promising adsorbent and catalyst supports. © 2013
BCREC UNDIP. All rights reserved
Keywords: Kaolin; acid/base treatment; physico-chemical characteristics; adsorbent; catalyst
How to Cite: Kumar, S., Panda, A. K., Singh, R.K. (2013). Preparation and Characterization of Acids and
Alkali Treated Kaolin Clay. Bulletin of Chemical Reaction Engineering & Catalysis, 8 (1): 61-69.
(doi:10.9767/bcrec.8.1.4530.61-69)
Permalink/DOI: http://dx.doi.org/10.9767/bcrec.8.1.4530.61-69

1. Introduction
Physical and chemical behaviors of clay minerals have been studied by numerous researchers due
to their adsorbing and catalytic properties. This behavior is governed by the extent and nature of their
external surface which can be modified by suitable
treatment techniques. There are broadly two different treatments or modification methods of clay

* Corresponding Author.
E-mail: sachin044@gmail.com (S. Kumar),
Tel: +91-66-2462260, Fax: +91-611- 2462022

minerals studied by different researchers such as
(1) physical modification (thermal or microwave
treatment) which involves alteration of chemical
composition and crystalline structure by the effect
of high temperature, (2) chemical modification (by
acids, bases, organic compounds) which is usually
by the alteration of structure, surface functional
groups and surface area [1].
The most common physical modification is thermal treatment which involves the alteration of
chemical composition and/or crystalline structure
by the effect of temperature. The structure and
composition of clay minerals can be modified by

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Bulletin of Chemical Reaction Engineering & Catalysis, 8 (1), 2013, 62
heating at high temperature [2]. Some physicochemical properties such as swelling, strength, cation exchange capacity, particle size, specific surface
area, surface acidity and catalytic activity as well
as mineralogy can change considerably on the thermal treatment [3, 4]. In addition to thermal treatment, microwave heat treatment also plays an important role for modification of clay materials [5].
Clark et al. has reported that the temperature and
time required by microwave heating method for
preparing adsorbents are far shorter than by the
conventional thermal activation method and this
method is simple, economic, time saving and energy efficient [6].
Acid treatment is one of the most common
chemical treatments for clay minerals and has
been used to increase the specific surface area and
the number of acidic centers, modify the surface
functional group and to obtain solids with high porosity. Numerous studies have been reported on
the acid treatment of clays, especially on bentonitesmectite or montmorillonite, vermiculite, kaolin,
palygorskite-sepiolite and glauconite [7-15]. The
various types of acids used for acid treatment including inorganic acids such as hydrochloric, sulfuric, nitric and organic acids such as acetic, citric,
oxalic and lactic. Among all of these, hydrochloric
acid and sulfuric acid are probably the most widely
used in acid activation, because it shows strong affection by the process parameters and superior results in specific surface area, porosity and adsorption capacity [16].
Hussin et al. has performed the basic treatment
of clay and reported that the active centers increases and surface area decreases with NaOH treatment and cost of sodium hydroxide is much lesser
than that of inorganic acids such as H 2SO4 and
HCl. However, the base treated clay materials are
suitable only for some applications [1].
Several problems such as corrosion of the process vessels, increasing of free fatty acids, peroxide
value in oil products and other environmental
problems occur when acid treated clay is used. This
led to modification of clay with cationic and anionic
surfactants [Cetyl trimethyl ammonium bromide
and linear alkyl benzene sulfonate] for the removal
color pigment, free fatty acids and peroxide value
[17]. Intercalation or pillaring is also a clay treatment method that alters the properties of bleaching earth by using combination of chemical and
physical treatments in which a layered compound
is transformed in a thermally stable micro and/or
mesoporous material with retention of the layer
structure. Pillared clay minerals have magnetized
much attention from the industry due to their microporous nature and catalytic potential [18, 19].
Recently, we have carried out the acid activa-

tion of kaolin with sulphuric acid of different concentrations under refluxed condition followed by a
systematic analysis of the treated kaolin samples
with wide characterization techniques to understand the changes in physico-chemical properties.
It has been concluded that sulphuric acid treatment at and above 5M concentration almost destroys the crystalline structure and other properties to a considerable extent [12]. Studies on different acids and alkaline treatment of kaolin with a
complete characterization and comparison of results have not been studied. Therefore, in the present work, kaolin is treated with different other acids such as HNO3, HCl, H3PO4, CH3COOH, and
base NaOH of 3 M concentration to compare their
effects on modifications in physico-chemical properties of kaolin after treatment with different reagents.
2. Experimental Works
2.1. Materials
The kaolin used in this experiment was procured commercially from Chemtex Corporation,
Kolkata, India. The sample was used as such without any further modification for the acid and alkali
treatment. The chemical composition of the sample
is as follows: SiO2 = 43.12%, Al2O3 = 46.07%, Fe2O3
= nil, MgO = 0.027%, CaO = 0.030%, ZnO =
0.0064%, K2O = 0.01%, TiO2 = 0.74% and loss on
ignition = 9.9%. From the proximate analysis and
XRD report it could be concluded that the major
component of the clay is kaolinite with Hinckley index of 0.4. Some traces of impurities (may be mica,
quartz and feldspar which could not be traced in
the XRD report) are also present which contribute
the components other than SiO2 and Al2O3 [12].
2.2. Acid Activation
The thermo-chemical activation was carried out
by adding 50 g of the clay to 500 ml of solution of
different acids and a base of 3 M concentration and
refluxing at 110 °C under the atmospheric pressure
in a round bottomed flask equipped with a reflux
condenser for four hours. The resulting clay suspension was then rapidly quenched by adding 500
ml ice cold water. The content was then filtered, repeatedly washed with distilled water to remove
any unspent reagent, dried in an oven, calcined at
550 °C for two hours and ground in a mortar pastel
to powder form. The untreated sample is referred
to as K and treated samples are referred to as
KHNO3, KHCl, KH3PO4, KCH3COOH, and KNaOH
in the subsequent text where the name refers to
the treated kaolin with different acid and base as
indicated.

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Bulletin of Chemical Reaction Engineering & Catalysis, 8 (1), 2013, 63
2.3. Characterization Techniques
The treated kaolin clay materials were characterized by X-Ray Fluorescence spectroscopy (XRF),
X-Ray Diffraction (XRD), Fourier Transformed Infrared Spectroscopy (FTIR), Thermogravimetric
Analysis (TGA), Differential Thermal Analysis
(DTA), Scanning Electron Microscopy (SEM), Temperature Programmed Desorption (TPD) ammonia
method, and by sorptiometric studies. The XRF
analysis of the samples were done by using a Model-PW2400 of Phillips with X-ray tube of rhodium
anode and scintillation detector with a current 40
mA and voltage 40 mV. The X-ray diffraction data
was collected using a Philips Analytical X-ray Instrument, X’Pert-MPD (PW 3020 vertical goniometer and PW 3710 MPD control unit) employing
Bragg–Brentano para focusing optics. The XRD
patterns were recorded in the range 2θ of 10–70°
with a scanning rate of 2 °/min. The FTIR spectra
were recorded on a Perkin-Elmer infrared spectrophotometer as KBr pellets with resolution of 4 cm1, in the range of 400-4000 cm-1. The sample and
analytical grade KBr were dried at 100 °C overnight prior to the FTIR analysis. The Thermogravimetric analysis were carried out by a SHIMADZU
DTG-60/60H instrument. A known weight of the
sample was heated in a silica crucible at a constant
heating rate of 10 °C/min operating in a stream of
N2 atmosphere with a flow rate of 40 ml/min from
35 - 600 °C. Nitrogen adsorption–desorption measurements (BET method) were performed at liquid
nitrogen temperature (−196 °C) with an Autosorb
BET apparatus from Quantachrome Corporation.
The BET analysis procedure is automated and operates with the static volumetric technique. Before
each measurement, the samples were outgassed
first at 200 °C for 2 hours, at 5 × 10−3 torr and then
at room temperature for 2 hours, at 0.75 × 10 −6
torr. The isotherms were used to determine the
specific surface areas using the BET equation. The
Scanning Electron Micrographs were taken on a
JEOL-JSM 5600 LV microscope, equipped with a
6587 EDS (energy dispersive X-ray spectrometry)
detector, using an accelerating voltage of 15 kV.
The samples were deposited on a sample holder
with an adhesive carbon foil and sputtered with
gold. The acidic properties of the catalysts were
probed by ammonia TPD measurements in Micromeritics 2900 TPD equipment. Previously, the
samples were outgassed under He flow (50
Nml/min) by heating with a rate of 15 °C/min up to
560 °C and remaining at this temperature for 30
min. After cooling to 180 °C, the samples were
treated with a 30 Nml/min ammonia flow for 30
min. The physisorbed ammonia was removed by
passing a He flow at 180 °C for 90 min. The chemically adsorbed ammonia was determined by in-

creasing the temperature up to 550 °C with a heating rate of 15 °C/min, remaining at this temperature for 30 min, and monitoring the ammonia concentration in the effluent He stream with a thermal conductivity detector.
3. Results and Discussion
3.1. XRF Characterization
The XRF analysis was carried out to know the
chemical compositions of the clay and the subsequent chemical changes that occurred due to treatment. Table 1 shows the results of chemical analysis of the parent and treated kaolin. The parent
clay contains alumina and silica which are in major quantities where as other oxides such as magnesium oxide, calcium oxide, potassium oxide, zinc
oxide and titanium oxide are present in trace
amounts.
After the acid treatment, it was observed that
the composition of the kaolin changes considerably.
The Al2O3, MgO, CaO, and K2O contents decreases
and SiO2 content increased in the treated kaolin
progressively on treatment with different reagents
(acids and base). The decrease in the alumina content in the treated sample can be ascribed to the
leaching of the Al3+ ions from the octahedral layer
due to hydrolysis under acidic/alkaline conditions.
During treatment, it was observed that the concentration of CaO, MgO, K2O, TiO2 and V2O5 reduced, but that of ZnO remained almost unchanged with any types of reagent. The extent of
leaching depends on the type of reagent and is in
the order NaOH = HNO3 > HCl > H3PO4 >
CH3COOH. For example, with 3 M NaOH and
HNO3 treatment, the Al2O3 content decreases from
46.07 to 29.30% and 27.88% respectively, where as
the SiO2 content increases from 43.12 to 56.14%
and 56.42% respectively. Thus the Si/Al ratio of
the kaolin treated with different reagent increases
in the same trend. The XRF study clearly indicates
that leaching occurred in a sequential manner due
to attack at tetrahedral layer resulting in the dealumination of clay. This can be interpreted due to
the increasing strength and leaching ability of the
respective reagents.
3.2. XRD Characterization
The structural changes that occurred in the
clay material after the acid or alkali treatment
were studied using X-ray diffraction technique.
Figure 1 shows the XRD profiles of the untreated
and treated kaolin samples. The parent clay shows
well defined reflections at 2θ value of 120, 250
(corresponding to the d values of 7.154 Å. These
peaks correspond to the reflections from [001],

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Bulletin of Chemical Reaction Engineering & Catalysis, 8 (1), 2013, 64
Table 1. XRF analysis of different kaolin
Material
Kaolin
KCH3COOH
KH3PO4
KHCl
KHNO3
KNaOH

Chemical content (% weight)
SiO2

Al2O3

MgO

CaO

K2O

ZnO

TiO2

V2O5

Si/Al

43.12
44.03
45.83
48.80
56.42
56.14

46.07
43.81
41.51
37.61
27.88
29.30

0.027
0.026
Nil
0.016
0.02
0.030

0.030
0.017
0.018
0.017
0.008
0.186

0.010
0.01
0.007
0.01
0.008
0.017

0.0064
0.0062
0.0064
0.0064
0.0064
0.0064

0.74
0.40
0.34
0.26
0.23
0.12

0.003
0.003
0.003
0.001
0.002
Nil

0.82
0.885
0.972
1.144
1.782
1.688

which are typical characteristic peaks of kaolinite.
After acid treatment, the peak intensity of the clay
was found to decrease and extent of decrease follows the trend HNO3 > HCl > H3PO4 > CH3COOH,
since leaching is quite severe with strong acids.
This is attributed to the structural disorder that
occurred owing to the acid leaching, which affects
the crystalline character of the clay. With NaOH
treatment the peak intensity increases and narrowed. The increase in intensity and/or narrowing
of the peak may be related to the increase of crystallite size and/or the decrease of the mean lattice
strain [20].
3.3. FTIR Characterization
The FTIR spectrums of kaolin and treated kaolins are shown in Figure 2 and the corresponding
band assignments are shown in Table 2. In the OH stretching region, the parent and acid treated
clay shows three prominent bands at 3620, 3653
and 3695 cm-1 corresponds to Al-OH stretching. Inner hydroxyl groups, lying between the tetrahedral

and octahedral sheets give the absorption at
3620cm-1. A strong band at 3695 cm-1 is related to
the in phase symmetric stretching and a weak absorption at 3653 cm-1 is assigned to out-of-plane
stretching vibrations. The band observed at 3445
cm-1, assigned to the high amount of water physisorbed on the surface of the clay [21, 22]. There
was not much variation in the peak pattern for 3 M
H3PO4 and CH3COOH acid treated kaolin. However with HNO3 and HCl treatment the peak intensity was found to decrease progressively indicating
penetration of protons into the clay mineral layers
and attack to the structural hydroxyl groups resulted in the dehydroxylation and a successive
leaching of the Al ions from the octahedral layer
[5]. For the NaOH treated kaolin the structural hydroxyl vibration band is extremely weak.
In the bending region mode, the clay materials
show a series of IR bands with peak maxima at
1634, 914, 795 and 755 cm-1. The peak at 1634 cm-1
is quite intense is attributed to the bending vibration mode of physisorbed water on the surface of

K

50

Counts

KHCl
KCH3COOH

KH3PO4

KHCl

KHNO3

KNaOH

40

30

%T

KNaOH

KCH3COOH

20
K

10
KH3PO4
KHNO3
10

15

20
25
30
Degree two Theta

35

40

0
1000

2000

3000

4000

cm-1

Figure 1. XRD results of different kaolin

Figure 2. FTIR results of different kaolin

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Bulletin of Chemical Reaction Engineering & Catalysis, 8 (1), 2013, 65
free silica produced due to leaching [22]. This peak
was found to be absent in case of the HNO 3 treated
clay due to structural disintegration. The IR peaks
at 914, 795 and 755 cm-1 can be assigned to the Al–
Al–OH, Al–Mg–OH and Si-O-Al vibration of the
clay sheet. The high intense 914 cm-1 peak due to
vibrations of inner OH groups was found to be
drastically reduced for HCl and HNO3 treated clay.
It can be concluded that, when the acid strength is
more the de-alumination process is facilitated rapidly, during acid treatment [23].
Again well resolved strong bands in the 11201000 cm-1 region is due to Si-O stretching in untreated kaolinite which changed in shape and position due to structural changes in the tetrahedral
cations. In addition, a new peak was observed at
805 cm-1 for the acid treated sample, which gained
intensity with increase in the acid strength [21,
23]. This peak is due to the formation of free amorphous silica. The FTIR result is in clear agreement
with the XRF and XRD studies which indicates sequential degradation of the clay sheet upon acid
treatment. The FTIR of KNaOH showed wide water bands centered at about 3420 and 1655 cm-1,the
asymmetric stretching of the tetrahedral units at
985 cm-1 with a shoulder at 1020 cm-1, the symmetric stretching at 665 cm-1, and the bending at 478
cm-1. Moreover, the presence of carbonate groups
was clearly shown by a wide band centered at 1440
cm-1.
3.4. TG-DTA Analysis
The TGA curves (Figure 3a) of the pure and
treated kaolin show two well-defined weight loss
regions due to the loss of physisorbed water (below
200 °C) and dehydroxylation of coordinated and
structural water (above 450 °C). In general, clay
materials contain three kinds of water molecules in
their structure. The physisorbed and interlayer

water is loosely bound and are mobile they can be
removed by heat treatment below 200 °C. The water molecules present in the first coordination
sphere of the interlayer ions are strongly bonded
and they require higher temperature in the range
of 300-500 °C for their removal. Finally, the structural hydroxyl groups can condense and dehydrate
in the temperature range of 500-800 °C. In the present study, the low temperature weight loss can be
assigned to the physisorbed water, where as the
high temperature weight loss is due to the dehydration and dehydroxylation of the clay sheet.
Comparing the TGA profile of the parent and the
acid treated clay it was observed that acid treatment increased the amount of physisorbed water
and it increased with increased strength of the acid
(HNO3 > HCl >H3PO4 > CH3COOH). It is extraordinarily high in case of sodium hydroxide treated kaolin. This may be due to the fact that chemical
treatment increased the amount of amorphous silica and also the surface area which made the water
adsorption higher. However, in the high temperature weight loss regions, the percentage loss is low
for treated clay as compared to the parent clay due
to the removal of octahedral Al ions along with the
concurrent removal of structural hydroxyl groups
after acid treatment.
The DTA profiles of the clay and acid treated
clay are shown in Figure 3b supports the weight
loss pattern due to water removal in the TGA
study. The DTA curve of untreated kaolin showed
two endothermic peaks at 56 and 531 °C. The endothermic peak centered at around 56 °C may be due
to physisorbed water and a large peak at 531 °C
might be due to the liberation of water caused by
dehydroxylation of co-ordinated and structural water molecules. Increase in acid strength due to
change in type of acid increased the physisorbed
water and decreased the structural and coordinated water leading to change in the endothermic

Table 2. Important IR assignments of different kaolin
Band (cm-1)

Peak Assignments

3445
3620, 3653 & 3695

Al--O-Hstr (physisorbed and interlayer water)
Al--O-Hstr (structural hydroxyl groups, octahedral

1634
912
1032, 1101 & 1114

H-O-Hbending(physisorbed)
Al–Al–OHstr,
Si-Ostr

795
755

Al–Mg–OHstr
Si-O-Alstr

805
693
541
472

Si-Ostr
Si-Ostr, Si-O-Alstr
Si-Ostr, Si-O-Alstr
Si-Ostr
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Bulletin of Chemical Reaction Engineering & Catalysis, 8 (1), 2013, 66
10
0

Heat Flow uV

-10
-20
-30
-40
-50
-60
-70

KNaOH
K
KCH3COOH
KH3PO4
KHCl
KHNO3

100

200

300

400

500

600

0

Temperature ( C)

Figure 3a. TGA of different kaolin

Figure 3b. DTA of different kaolin

peaks in treated samples. The thermal analyses of
the alkaline treated sample showed completely different curve as compared to acid treated kaolin
samples. Thus, the weight loss is very high at low
temperature, between room temperature and 250 °
C. It may be considered that the fixed carbonate
anions contributed in a small amount to the weight
loss at high temperature.

from destruction and leaching of kaolin, by removal of different cations plugging the surface pores or
interlamellar spaces, by formation of surface pores
and cracks as well as by decrease in mineral size
leading to increased pore volume due to acid treatment. Under alkaline treatment, similar processes
may occur together with an accumulation of hydroxides of Mg and Ca [24].

3.5. BET Surface Area and Pore Volume

3.6. SEM Analysis

The surface area and pore volume of the pure
and treated kaolin obtained using N 2 adsorptiondesorption isotherms summarized in Table 3. The
pore volume and BET surface area increased with
increasing acid strength. Alkali treatment also increased the surface area and pore volume. This can
be explained due to occurrence of the dealumination process and thus surface disintegration.
The increase in pore volume due to acid treatment is more prominent as compared to alkali
treatment. Production of finely dispersed Si oxides

The scanning electron micrographs of the different kaolin clay samples are presented in Figures
4(a-f) which shows the morphological features. The
SEM micrograph of KC reveals the presence of
large particles that appeared to have been formed
by several flaky particles stacked together in form
of agglomerates. The SEM images of treated kaolin
show different particles morphology. The micrographs of KCH3COOH and KH3PO4 indicate the
disaggregation and decrease in size of clay structure on acid treatment and that of KHCl, KHNO 3
and KNaOH shows well-bonded aggregates rather
than detached particles.

Table 3. BET surface area and pore volume of different kaolin

Kaolin

Surface Area
(m2/g)
23

Pore Volume
(cc/g)
0.361

KCH3COOH

38

0.504

KH3PO4

42

0.658

KHCl

78

1.083

KHNO3

86

1.124

KNaOH

76

0.591

Material

3.7. Acidity of Kaolin
The acidity of aluminosilicates is characterized
in terms of Bronsted and Lewis acid sites.
Bronsted acid sites are formed by aluminum atoms
connected to silicon by a so-called ‘‘bridging hydroxyl’’ Al–(OH)–Si where the negative charge generated is compensated for by a proton. Lewis acid
sites are composed of aluminum with low coordination or ≡Si+ ions formed from dehydroxylation.
Therefore, the acidity of an alumino-silicate is related to its silica and aluminum contents, and in-

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Bulletin of Chemical Reaction Engineering & Catalysis, 8 (1), 2013, 67

(a)

(b)

(c)

(d)

(e)

(f)

Figure 4. SEM images of treated kaolin by: (a) Kaolin clay; (b) CH3COOH; (c) H3PO4; (d)
HCl; (e) HNO3; (f) NaOH

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Bulletin of Chemical Reaction Engineering & Catalysis, 8 (1), 2013, 68
0.10

Table 4. Acidity values of different kaolin
Acidity (mmol/g)

0.08

Kaolin
KCH3COOH

0.049
0.109

0.06

KH3PO4
KHCl
KHNO3

0.114
0.225
0.341

KNaOH

0.112

creases linearly with increasing silica to aluminum
ratio in the sample (Table 1). Acidity values of pure
kaolin and acid, alkaline treated kaolin is shown in
table 4. Lower acidity of KNaOH can be explained
due to the neutralization of acid sites formed due
to leaching by the strong alkali NaOH.
Figure 5 shows typical plots of ammonia desorption rates as a function of temperature for samples
so treated. It can be seen from TPD plots that desorption of ammonia from all the samples starts at
about 200 °C and ammonia desorption plots of
samples Kaolin Clay (KC), KCH3COOH, KH3PO4
contain two peaks. In case of the first peak, that
occurs at 200-300 °C is assigned to desorption of
ammonia from Lewis acid sites as week coordinate
bond will break at low temperature. The second
weak peaks at around 500-600 °C is due to desorption of Bronsted acid bound (strong ionic bond) ammonia molecules. Similarly, the plots of the ammonia desorption for samples KHCl and KHNO3 contain three peaks out of which first one is due to
Lewis acid sites which is at lower temperature and
other two at higher temperature may be due to
Bronsted acid sites. The lower ammonia desorption
rate and as a result the less acidity were found to
be on KC, KCH3COOH, and KH3PO4 samples. Due
to the low Si/Al-ratio of these kaolinite samples
both SiOH and AlOH sites are center responsible
for the ammonia adsorption. Slightly high acidity
is due to dealumination. Other two samples KHCl
and KHNO3 have more acidity due to higher rate of
desorption.
4. Conclusion
The effect of the acid and alkaline treatment on
the structural and chemical properties of kaolin
clay has been studied. The XRF and SEM study indicated clearly the leaching and disintegration of
the clay sheet after treatment with different acid
and alkali. The Al2O3, MgO, CaO, K2O, TiO2, and
ZnO contents in the treated material decreased
progressively simultaneously increasing the SiO 2

TCD (a.u.)

Materials

KNaOH
K
KCH3COOH
KH3PO4
KHCl
KHNO3

0.04

0.02

0.00
200

300

400
0 500
Temperature ( C)

600

Figure 5. TPD NH3 plots of different kaolin

content. XRD studies of the acid treated clay indicated the structural transformation of the clay
sheet upon acid treatment. After acid treatment
the peak intensity of the clay was found to decrease and extent of decrease follows the trend
HNO3 > HCl > H3PO4 > CH3COOH. FTIR spectrum
of the acid treated kaolinite clay shows that there
is not much variation in the peak pattern for
H3PO4 and CH3COOH acid treated kaolin. The
peak intensity is found to decrease progressively
for HNO3 and HCl acid treated kaolin and for
NaOH treated kaolin, the structural hydroxyl vibration band is extremely weak. TGA profile of the
parent and the acid treated clay shows that acid
treatment increased the amount of physisorbed
water and it increased with increased strength of
the acid (HNO3 > HCl > H3PO4 > CH3COOH). It is
extraordinarily high in case of sodium hydroxide
treated kaolin. The DTA profiles of the clay and acid treated clay supports the weight loss pattern
due to water removal in the TGA study. The increase in pore volume and BET surface area due to
acid treatment is more prominent as compared to
alkali treatment. The SEM micrograph of KC reveals the presence of large particles which are aggregated after treatment with HCl, HNO3, NaOH
and disaggregated when treated with H 3PO4 and
CH3COOH. The acidity was less in case of pure kaolin and after treatment with CH3COOH and
H3PO4 acids while HCl and HNO3 acids treated kaolin have more acidity.

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Bulletin of Chemical Reaction Engineering & Catalysis, 8 (1), 2013, 69
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