Applied Clay Science 132–133 (2016) 194–204

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Applied Clay Science

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Potentials of fabricating porous ceramic bodies from kaolin for catalytic
substrate applications
David O. Obada a,⁎, David Dodoo-Arhin b, Muhammad Dauda a, Fatai O. Anafi a,
Abdulkarim S. Ahmed c, Olusegun A. Ajayi c,d

a Department of Mechanical Engineering, Ahmadu Bello University, Zaria, Nigeria
b Department of Materials Science and Engineering, University of Ghana, Legon, Ghana
c Department of Chemical Engineering, Ahmadu Bello University, Zaria, Nigeria
d Department of Chemical and Petroleum Engineering, Afe Babalola University, Ado-Ekiti, Nigeria
⁎ Corresponding author.
E-mail address: obadavid4@gmail.com (D.O. Obada).

http://dx.doi.org/10.1016/j.clay.2016.06.006
0169-1317/© 2016 Elsevier B.V. All rights reserved.
a b s t r a c t
a r t i c l e i n f o
Article history:
Received 9 January 2016
Received in revised form 3 June 2016
Accepted 7 June 2016
Available online 16 June 2016
In this work, the suitability of using kaolin–styrofoam, sawdust, and high density polyethylene to produce porous
ceramic bodies was experimentally investigated. The kaolin samples (raw and beneficiated) were characterized
by the XRD, SEM, TGA/DSC and FTIR methods. Batch formulations of the samples including the kaolin and pore
formers were formed into green bodies and fired to 1150 °C. The porosities of sintered bodies were calculated
and gave the following: apparent porosity: 28.63%–67.13% for all the samples investigated. Samples with high
density polyethylene (HDPE) pore formers showed minor surface cracks after firing, but exhibited the highest
porosity levels while samples with styrofoam and saw dust exhibited uniform surface characteristics with
pores, thermal stability and no visible surface cracks. It can be concluded that formulations containing 80% kaolin
can be used for the production of ceramics with porosities as high as 67% if the right pore formers are used.

© 2016 Elsevier B.V. All rights reserved.
Keywords:
Kaolin
Porosity
Physical properties
Pore formers
Green bodies
1. Introduction

The presence of porosity in materials for industrial applications is
often viewed as problematic. However, there are many applications in
which the use of porous materials can be advantageous or even neces-
sary, for example in filters, membranes, catalytic substrates, thermal in-
sulation, gas burner media, and as refractory materials. Generally,
porous ceramics are usually understood as materials having porosity
levels which are over 30% (Guzman, 2003). They could be considered
as systems that consist of a solid substance that forms walls between
pores (a skeleton) and air that normally fills the pores. The composition,
pore characteristics, and crystal structure are the main parameters
determining the thermo-physical properties of porous ceramics
(Ulyanova et al., 2006). Various processing routes/methods have been
applied in manufacturing porous ceramics and they have recently
been reviewed by Studart et al. (2006). These methods include but not
limited to replica, sacrificial template and direct foaming methods
while many other techniques are being developed, where a change of
a host of parameters leads to different types of product from the same
startingmaterials. The development of porous ceramics is attractive be-
cause porous ceramics aremore stable in severe environments and they
can be engineered to satisfy specific requirements due to their surface
characteristics. Various porous media such as metal foams (Dukhan,
2012),wood (Kim andPal, 2010), porous polymers (Liu et al., 2014), po-
rous nano-composites (Li et al., 2012) and ceramic foams (Colombo,
2002) have been used for a variety of industrial applications in battery
electrodes, vehicular furnishing, catalytic converters, etc. Amongst the
porous materials, there has been an increasing demand for porous ce-
ramics in industrial applications due to their high temperature stability
and the ability to tailor their pore sizes for specific operations. (Efavi et
al., 2012; Hammel et al., 2014).

Porous ceramic bodies are usually made from aluminosilicates and
several technologies are available for their fabrication (Chen et al.,
1998; Sandford and Sibley, 1996). The nature of raw materials used in
the various fabrication routes however affects the porosity (pore size),
surface, chemical inertness and also the thermal shock resistance of po-
rous ceramic bodies (Taslicukur et al., 2007).

Kaolinite has gained a lot of research interest due to its relative sim-
plicity both structurally and chemically. Though it usually contains a va-
riety of structural defects, the structural orderliness of these kaolinites
tend to influencemany of the properties which are exploited industrial-
ly. Kaolinite and more specifically ordered kaolinite have been found to
be of immense application in alum and alumina production (Al-Zahrani
andAbdel-Majid, 2004; Hosseini et al., 2011), ceramics, zeolite catalysts,
catalyst supports for auto-exhaust purification, adsorbents for heavy

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Fig. 1.Map of (a) Kibi, Eastern region of Ghana and (b) Kankara, Katsina Region of Nigeria.

195D.O. Obada et al. / Applied Clay Science 132–133 (2016) 194–204



Table 1
Composition of Batch formulation (Total weight = 100 g).

Sample code. Kaolin (g) Plasticizer (Kibi Kaolin) (g) Saw dust (g) Styrofoam High density polyethylene (HDPE)

A 70 20 10 – –
B 60 20 20 – –
C 70 20 – 10 –
D 60 20 – 20 –
E 70 20 – – 10
F 60 20 – – 20
G 80 20 – – –

196 D.O. Obada et al. / Applied Clay Science 132–133 (2016) 194–204
metals and currently in catalysis, tomention a few (Murray, 2000, 2007;
Bergaya et al., 2006; Murray and Kogel, 2005; Churchman et al., 2006;
Adams and McCabe, 2006).

Properties of kaolinite, particularly important for industrial applica-
tions are particle-size distribution, structural order-disorder or crystal-
linity, surface area and whiteness (Murray, 2000). The order degree of
kaolinites strongly influences their physical and chemical properties.
Themost often usedmethod for examination of the degree of structural
disorder or “crystallinity” of the kaolinite samples is X-ray powder dif-
fraction. The XRD patterns of ordered kaolinite samples are significantly
different from those of disorder. Ordered kaolinite shows sharp and
Fig. 2. Particle size distribution of Kankara and Kibi Kaolin.
narrow peaks, while its disordered counterpart gives less well-defined,
broad, and asymmetrical peaks (Brigatti et al., 2006). The crystallinity
indices given bymany authors are widely used for determination of ka-
olinite disorder degree using various approaches based on X-ray diffrac-
tion (Brindley et al., 1963; Plancon and Zacharie, 1990; Aparicio and
Galán, 1999; Chmielová and Weiss, 2002; Aparicio et al., 2006). Also it
has been observed that less common method used for determination
of kaolinite disorder degree is infrared spectroscopy. The structural dis-
order of kaolinites can be detected by differences in position and rela-
tive intensity of OH stretching and bending bands in IR spectrum
(Madejová and Komadel, 2001; Muller and Bocquier, 1987; Prost et
al., 1989).

Numerous pore-forming agents have been investigated, including
starch (Zivcová et al., 2012; Khattab et al., 2012; Garrido et al., 2011;
Chen et al., 2011; Zivcová et al., 2009; Zivcová et al., 2010; Gregorová
et al., 2006), graphite (Sarikaya and Dogan, 2013; Sanson et al., 2008;
Ding et al., 2007; Boaro et al., 2003), lycopodium (Zivcová et al., 2007;
Zivcová et al., 2008; Seržane et al., 2010), sucrose (Sarikaya and
Dogan, 2013: Ray et al., 2010;Wang et al., 2005) and polymethyl meth-
acrylate (Zeng et al., 2007; Yao et al., 2005; Kumar et al., 2005) and
others (Bai et al., 2012; Horri et al., 2012 and Silva et al., 2002). Even
though starch is the most frequently used pore forming agent, possibly
due to its biological origin and availability, the difficulties inmaintaining
the pore structure formed by the starch burn out, and the narrow
size range of commercially available starch types (typically between
5 and 50 μm) limits its application when large pores are desirable
(Gregorová and Pabst, 2007).

As stated, a lot of pore-forming agents have been investigated, how-
ever, to the best of our knowledge, no report regarding the use of pow-
dery high density polyethylene (PHDPE) has been reported so far for its
potential in creating voids in a ceramic body after solid state sintering.
Hence, this experimental investigation therefore aims to develop ce-
ramic bodies from kaolin deposits sampled from Kankara and Kibi re-
gions in Katsina-Nigeria and Kibi-Ghana using sawdust, high density
polyethylene and styrofoam as pore formers.

2. Experimental methods

2.1. Raw material beneficiation and powder preparation

The two kaolin samples used were mined from deposits at Kankara
in Katsina State of Nigeria and Kibi in the Eastern region of Ghana as
shown in Fig. 1.

The raw mined kaolin samples were washed off their impurities by
adding water to a constantly stirred kaolin blunger to obtain slurry
with specific gravity of about 1.2. The slurry was then passed through
a 350 μm sieve to eliminate coarse grained impurities; poured into a
Plaster of Paris mold (POP) and the filtrate dried in an oven at a temper-
ature of 120 °C for 7 h. The essential properties of the rawmaterial such
as particle size rangeswere experimentally determined. A lasermethod,
low-angle laser light scattering (LALLS), was used for the particle size
analysis with levels of sensitivity in the 0.3 nm to 8 μm range using a
Horiba Scientific, SZ-100 nanoparticle analyzer. 10 mg of the kaolin
samples (Kankara and Kibi) plus freshly deionized water (10 mg of



Table 2
Chemical compositions of the Kankara and Kibi kaolin.

Component SiO2 Al2O3 Fe2O3 TiO2 MgO CaO Na2O K2O CuO LOI*

KKR fraction (wt%) 54.30 28.32 0.84 0.10 0.44 1.90 0.22 3.94 0.02 9.77
KKB fraction (wt%) 51.50 28.20 0.91 0.12 0.47 1.21 0.61 1.80 0.02 15.01
KBB fraction (wt%) 45.81 39.24 0.95 1.46 ND 0.01 0.02 0.84 0.01 11.09

LoI* = Loss on ignition, KKR = Raw Kankara Kaolin; KKB = Beneficiated Kankara Kaolin; KBB = Beneficiated Kibi Kaolin.

197D.O. Obada et al. / Applied Clay Science 132–133 (2016) 194–204
kaolinite +10 mL of water) were subjected to continuous ultrasound
treatment in an ultrasonic bath for 15mins to ensure dilution and ho-
mogenousdispersion. The pore formers comprising sawdust, styrofoam
and high density polyethylenewere prepared using an analytical mill to
reduce the sizes.

2.2. X-ray fluorescence (XRF)

The chemical compositions of the samples were determined using a
Panalytical Minipal 4 X-ray fluorescence analyzer equipped with
Omnium software for analysis. The samples weremilled to achieve par-
ticle sizes b75 μm, dried at 100 °C and roasted at 1000 °C to determine
Loss on Ignition (LOI) values. About 1 g of each sample was mixed with
6 g lithium tetraborate flux (Li2B4O7) and fused at 1050 °C to obtain a
stable fused glass bead. For trace elemental analyses, the sample was
mixed with a PVA binder and pressed into a pellet.

2.3. XRD analysis and crystallinity index

To determine the crystalline domain size, phases present, and the
kaolinite order X-ray powder diffraction (XRD) patterns were collected
on an Empyrean diffractometer (Panalytical BV, Netherlands) with
theta/theta geometry, operating Cu Kα radiation tube (λ = 1.5418 Å)
at 40 kV and45mA. TheXRDpatterns of all the randomly oriented pow-
der specimenswere recorded in the 5.0°–70° 2θ rangewith a step size of
0.017° and a counting time of 14 s per step. The diffraction patterns
were matched against the ICSD's PDF database and qualitative phase
analysis conducted using the X'Pert Highscore plus search match soft-
ware (Panalytical, The Netherlands). The order of the kaolinite samples
was determined using theHinckley index (HI) (Hinckley, 1963). The es-
timated average crystallite sizes of the kaolinite samples were also cal-
culated from the X-ray diffraction pattern by using the Scherrer
broadening method based on the basal 002 reflection with peak
Fig. 3. XRD patterns of raw Kankara kaolin, beneficiated Kankara kaolin and Kibi kaolin.
Kaolinite (K), Illite (I), Muscovite (M) and Quartz (Q).
position at (26.8°, 2θ) and the 001 plane at 12.8°, 2θ (Scherrer, 1918).
The Scherrer equation is given as βð2θÞ ¼ Kλ

L cosθ where K is the Scherrer
constant for shape factor vales, λ is the wavelength of the radiation
source, θ is half of the diffraction angle, β is the peak width (Full
width at Half Maximum-FWHM) and L is the crystallite size.

2.4. Fourier infrared spectroscopy

To further probe the structure, quality andfigure prints of the kaolin-
ite samples, Attenuated Total Reflectance (ATR) Fourier Transform Mid
Infra-Red spectra were recorded on a HYPERION 3000 (Bruker Optics)
instrument in the 4000–400 cm−1 range with a resolution of 2 cm−1.
The powder samples were measured without the addition of KBr. Sam-
ple compartment was evacuated during acquisition and the contact be-
tween the sample and the Attenuated Total Reflectance (ATR) diamond
crystal was 2 mm diameter.

2.5. Thermogravimetry

The thermal stability of the various phases in the samples was stud-
ied byDTA/TGunder airflowof 50mL/min. The sampleswere thermally
analysed by placing ≈25 mg of the specimens in an alumina (Al2O3)
crucible (100 mg capacity), subjected to a linear heating ramp between
100 °C and 700 °C at a rate of 10 °C/min and a cooling rate of 50 °C/min,
in NETZSCH, STA 449C Jupiter TG/DSC instrument. The test measure-
mentsweremade for themass change (loss) of the sample as a function
of the temperature and the phase changes by the adsorption or the
emission of energy.

2.6. Scanning electron microscopy

Scanning electron microscopy analysis was conducted to study the
morphological features of the various layers of the kaolinite samples
using anultra-high vacuumand high resolution FEI,Xl-30 scanning elec-
tron microscope. Samples were metalized with gold/platinum coating
prior to the analysis. Images were acquired at magnifications of
8000× and 15,000× and 10,000× for kaolinites and at 500× for sintered
samples.

2.7. Formation of porous green bodies

Different sets of batch formulated samples composed of Kankara and
Kibi kaolin and pore formers (sawdust, high density polyethylene and
styrofoam) were mixed with water and kneaded to eliminate lumps,
trapped air bubbles and to ensure homogeneity. (see Table 1 for de-
tailed compositions of samples). The sample without pore former has
been used as a control sample. The samples have been coded A, B, C,
D, E, F and G. A and B are ceramic bodies with 10 and 20wt% of sawdust
as pore former, C and D are ceramic bodies with 10 and 20wt% of styro-
foam as pore former E and F are ceramic bodies with 10 and 20 wt% of
HDPE as pore former while G is the control sample with no pore former
(100% kaolin).

Since Kibi kaolin was experimentally observed to be more plastic, it
was used mainly as a plasticizer in the batch formulations. The kaolin-
pore formermixturewas then completely filled into amold and pressed
to the same level to ensure compactness and dimensional homogeneity.



Fig. 4. SEM and EDS of raw Kankara kaolin.

198 D.O. Obada et al. / Applied Clay Science 132–133 (2016) 194–204
The as-prepared green body samples were removed from the mold and
dried at room temperature (ca. 25 °C) on boards for three (3) days after
which they were further dried at 100 °C to remove moisture. This in-
creased their green strength and made them safe for subsequent han-
dling. The dried batch-formulated green bodies were then sintered at
1150 °C for 2 h in an electric muffle furnace at a heating rate of 5 °C/
min. The apparent porosity (the amount of void or pores within a vol-
ume of porous solid) of the as-sintered kaolin based ceramic bodies
was calculated using Eq. .(1):

Apparent porosity ¼ W−D
W−S

� �
� 100 ð1Þ

where:W=Weight of soaked specimen suspended in air; D=Weight
of fired specimen and S = Weight of fired specimen suspended in
water.

3. Results and discussion

3.1. Sieve size analysis

The particle size distribution of the kaolin samples (Kankara and
Kibi) after particle size analysis is shown in Fig. 2. There is a broad
range of particle sizes in the samples (b1 nm–8000 nm)which is neces-
sary for close packing configuration (Kingery et al., 1976; Richerson,
2006).

Table 2 presents the chemical analysis of the rawKankara kaolin and
beneficiated Kankara and Kibi kaolin. There was no appreciable reduc-
tion in MgO, CuO and TiO for the Kankara kaolin. MgO was also not
Fig. 5. SEM and EDS of bene
detected in the Kibi Kaolin. Nevertheless, some appreciable reductions
were observed in the K2O and CaO after beneficiation for the Kankara
and Kibi Kaolin. For the Kankara kaolin which is the base material, K2O
reduced by 54.3% while CaO reduced by 36.31%. The reductions ob-
served vis-à-vis rawkaolin generally, likely occurred as a result ofwash-
ing off of soluble salts of potassium and calciumduring the beneficiation
process. It is worth noting that Na2O and Fe2O3 had rather increased for
the Kankara Kaolin after the beneficiation. It was not clear what was re-
sponsible for the increment, however, the same trendhave been report-
ed for Kankara clay by other researchers (Edomwonyi-Otu, et al., 2013).
The LOI of the raw Kankara kaolin was 9.77 wt%, it increased by 34.9%
after beneficiation. The increase after beneficiation could be attributed
to increase in clay content of the kaolin resulting from washing away
of impurities.
3.2. XRD patterns and Hinckley index of kaolinite

Fig. 3 presents the XRD pattern of the raw and beneficiated Kankara
kaolin (KKR and KKB) in addition to beneficiated Kibi kaolin (KBB). The
rawmaterial is composed of kaolinite, quartz andmontmorillonite. (See
Figs. 4 and 5.)

The beneficiated kaolin is mainly composed of kaolinite. The reduc-
tion in the intensity of the quartz could be attributed to reduction in the
concentration due to washing away during the beneficiation process.
The same can be said for theXRDpattern of KBB. Themain characteristic
peaks of kaolinite (12.35° and 24.88°) have also been observed. The
narrow and intense peaks confirm that these kaolinites are well
crystallized.
ficiated Kankara kaolin.



Fig. 6. Comparison of TG curves for raw and beneficiated Kankara kaolin and beneficiated
Kibi kaolin.

Fig. 8. Comparison of FTIR spectra of raw and beneficiated Kankara kaolin.

199D.O. Obada et al. / Applied Clay Science 132–133 (2016) 194–204
The Hinckley index for beneficiated Kankara kaolin was found to be
0.9199 while that of Kibi Kaolin was found to be 1.313. This indicates
that the Kibi kaolin ismore crystalline than the Kankara kaolin. From lit-
erature (Scherrer, 1918), the common K values include 0.89–1.0 for
spherical crystalswith cubic symmetry and from0.62 to 2.08 for various
crystal structures. The average crystallite sizes for Kibi kaolin are
32.109 nm (K = 0.62), 51.79 nm (K = 1), 107.724 nm (K = 2.08) and
that of Kankara kaolin are 12.969 nm (k = 0.62), 20.51 nm (k = 1),
43.51 nm (k = 2.08).

3.3. SEM micrographs of Kankara and Kibi kaolin

Plates I, II, III and IV show the SEM images of the raw and
beneficiated Kankara and Kibi kaolin respectively, scanned at various
magnifications. The platelet morphology of kaolinite clay reported in
the literature (Abo-El-Enein et al., 2013; Bergaya and Lagaly, 2013)
which normally portrays booklets morphology could be clearly ob-
served. Plates I and III (A and B) show the SEM scan at magnifications
of 8000 and 15,000× for the raw kaolin (Kankara and Kibi) while
Plates II and IV (A and B) show the SEM scan at magnifications of
8000 and 15,000× for the beneficiated kaolin (Kankara and Kibi). Each
of the images showed a booklet morphology consisting of platelet
Fig. 7. Comparison of DSC curves for raw and beneficiated Kankara kaolin and beneficiated
Kibi kaolin.
sheets of kaolinitemineral as reported in the literature. The average par-
ticle size was estimated as 2.0 μm for both the raw and beneficiated
kaolin.
3.4. Thermogravimetric behaviour of kaolin samples

Figs. 6 and 7 show the TG/DSC curves of the KKR, KKB and KBB. It
could be observed from Fig. 6 that the threematerials have similar ther-
mogravimetric curves. The TG curves show the weight loss associated
with thermal treatment of Kankara kaolinite up to 700 °C. It can be ob-
served that the remarkable loss occurred between 450 °C and 600 °C
and stabilized at about 700 °C for beneficiated Kankara kaolin. As
regards the beneficiated Kibi kaolin, it was observed that the remark-
able loss occurred between 500 °C and 550 °C and stabilized around
600 °C and for the rawKankara Kaolin, it was observed that the remark-
able loss occurred between 450 °C and 600 °C and stabilized at about
700 °C. These correspond to a transformation of phase from the crystal-
line kaolinite to the amorphousmetakaolin for all thematerials. This ob-
servation is corroboratedwhere dehydroxylation of Kankara kaolinite is
seen between 500 °C and 600 °C for the kaolinite corresponding to a
weight loss of about 9.4%, 8.0% and 14.8% respectively in agreement
with literature expectations (Bich et al., 2009).

Both curves depicted in Figs. 6 and 7, for TGA andDSC, are of a typical
shape for kaolin based materials. Since the sample was not fully dried,
some physically bounded water was present at the surface defects on
walls of kaolinite crystals (Polakovič et al., 1983) and in micropores,
which caused a subsequent loss of the sample mass at the lowest tem-
peratures. This is as confirmed by the endothermic peaks as shown by
the DSC curve around 100 °C. From the TG curve, absorbed water is
gradually evolved at temperatures up to 200 °C. The dehydroxylation
reaction occurs in the temperature range of about 450°–700 °C. Experi-
mental factors, such as the heating rate, large sample particle size and so
on can shift the initial and final temperatures of the dehydroxylation,
hence the slight differences in mass depletion of the three materials.

Fig. 7 shows a typical DSC plot of the threematerials and offer a basis
for comparison. The following peaks can be observed: desorption of
water from ambient to 110 °C (Endotherm) for raw and beneficiated
Kankara kaolin and dehydroxylation of the crystal lattice (450–700 °C)
(Endotherm process with a Tmin = of about 528.56 °C) for all the
three materials. The phase transformation of the beneficiated kaolin at
a lesser temperature tometakaolin plays a key role in the thermal stabil-
ity of kaolin based ceramics during sintering.



Fig. 9. Green bodies during drying at room temperature.

Fig. 10. Sintered bodies at 1150 °C. a) Sample with styrofoam b) Sample with PHDPE c)
Sample with sawdust d) Sample without pore formers.

200 D.O. Obada et al. / Applied Clay Science 132–133 (2016) 194–204
3.5. FTIR analysis

Fig. 8 shows the FTIR analysis of Kankara kaolin (raw and
beneficiated kaolin). The absorption bands at 3698.1–3619.9 cm−1

and 3697.6–3620.4 cm−1 express the stretching vibrations of OH
groups of kaolinite for raw and beneficiated kaolin respectively
(Antunes et al., 2013; Galos, 2011; Gasparini et al., 2013). The bands lo-
cated at 3441.1 and 1116.1 cm−1 and 3441.1 and 1115.9 cm−1-

corresponds respectively to stretching vibrations of water molecules
(Yusiharni and Gilkes, 2012) while those at 1031.8 cm−1 and
1031.9 cm−1 and then at 912.0 cm−1 and 912.7 cm−1 express respec-
tively the vibrations of Si- O– Si and Si- O– Al groups of the network.
The bands at 789.7 and at 694.9 cm−1, and 796.2 and 693.0 cm−1 indi-
cates the presence of the stretching vibration of Al-OH with Al in coor-
dination for raw and beneficiated kaolin respectively. The band at
477.7 cm−1 and 479.6 cm−1 indicates the vibrations of Si-O-Si and Si-
O-Al groups of the network for the raw and beneficiated kaolin respec-
tively. In summary, the spectra exhibitedOH stretching at bands 3698.1,
3619.9 3697.6 and 3620.4 cm−1 respectively, and the OH deformation
bands were observed at 912.0 and 912.7 cm−1 for the raw and
beneficiated samples tested respectively. Bands associated with SiO
stretching were 789.7, 694.9, and 796.2 and 693.0 cm−1 respectively,
whereas SiO deformation bands were 1031.8 and 1031.9 cm−1. It is ob-
served that the bands obtained for raw kaolinite are close to those ob-
tained for beneficiated kaolinite.

3.6. Formation of porous green bodies

Fig. 9 shows compacted images of dried green bodies ready forfiring.
The green body's strength is important because a weak green body is
likely to shatter in the course of sintering. After the drying period, it
was observed that the samples with high percentage of pore formers
(sawdust, styrofoam and high density polyethylene) either cracked or
warped (twist). This observation is attributed to the nature of the pore
formers used. After firing, the high density polyethylene formed sam-
ples had some surface cracks, high porosity, uneven cleavages in broken
samples, not too noticeable discoloration and distorted dimension (Fig.
10). These characteristics are attributed to the nature of pore formers
used. This observation indicates that the disintegration of the fired sam-
ple results from release of large volume of CO2, H2O vapour and other
gaseous volatiles during firing.

Most of the porous ceramics did not show any significant sign of dis-
coloration despite the release of large volumes of CO2 from the combus-
tible pore formers. This could be attributed to complete burn out of
organic solvents and the transition of green bodies from hydrous to an-
hydrous states after the evaporation effect is over. This tendency is ob-
served at higher temperatures. The samples after firing exhibited
some thermal stability and compactness without indications of severe
surface cracks or distortions. This is attributed to lowermelting temper-
atures of the pore formers. It is commonly believed that the relatively
large volume change accompanying theβ→α transformation of theun-
solved quartz grains (ΔV/V=−0.68% for free quartz grain) is the basic
source of microcracking. After removing the weakly bound physically
absorbed water, the sample loses the rest of this water and a very
small amount of the organic material. The values of the thermal expan-
sion increase up to ∼500 °C when dehydroxylation occurs, which leads
to a contraction of the sample and dropping of its mass. Following the
escape of the physically bound water, there is no further change in the
structure and composition. The temperature interval of dehydroxyl-
ation is considered a critical stage of the firing process. It is known
that an inadequate high rate of heating or cooling leads to cracking of
the ceramic body. This was only observed significantly on samples E
and F which can also be attributed to the high porosity in the samples.
Fig. 10 shows the ceramic bodies after sintering.

Fig. 11 show SEM images of control sample and sampleswith 10wt%
of pore formersfired at 1150 °C for a holding time of 2 h. It was seen that
bothmacropores andmicroporeswere interconnected. From images A–
C some cracking or intervening pore walls were also seen due to the
fraction of pore formers embedded (10wt%). It can be observed that im-
ages A–C show the porosities that have been embedded into the sam-
ples by virtue of the combustible pore formers (large dark holes in the
images), while image D, by reason of experimentation showed some
visible pores not comparable to the others, and obviously had very lim-
ited pores embedded. This is in line with results obtained for apparent
porosity (see Table 3), where it was noted that materials with porosity
levels less than 30% cannot be said to be porous.



Fig. 11. SEM images of sintered samples: A) Sample with Styrofoam B) Sample with high density polyethylene C) Sample with sawdust D) Sample without pore formers.

201D.O. Obada et al. / Applied Clay Science 132–133 (2016) 194–204
Generally, porous ceramics are usually understood asmaterials hav-
ing porosity over 30% (Guzman, 2003). The apparent porosity of the ce-
ramic bodies increased with increasing amount of sawdust, styrofoam
and high density polyethylene in the samples. Apparent porosity as
high as 67% was calculated for the sample containing the high density
polyethylene as pore formers confirming the potential of the kaolin de-
posits in forming porous bodies for industrial application. Sample with
the HDPE gave the highest porosity of 67.13% while sample G showed
the lowest value of 28.63%. Sample G which is the sample of batch
mix containing only kaolin is seen to have less pores by virtue of the ab-
sence of porogenic materials, hence, it can be said that sample G is a
non-porous sample. This assertion is in line with Guzman (2003).
Also, it can be rightly observed that the higher the percentage weights
of pore formers in a sample, the higher the porosity. This is for the obvi-
ous reasons of the porogen creating more voids in the sample.
Plate I. SEM images of raw Kankara kaolin at m
4. Conclusions

The viability of producing porous ceramic bodies fromWest African
regional kaolin deposits using various pore formers at elevated temper-
ature (≈1150 °C) for catalytic substrate applications has been success-
fully explored. The XRD analysis of the samples using the Hinckley's
index and Scherrer theory indicates that the Kibi kaolin which was
used as a plasticizer was well ordered than the Kankara kaolin. This
wasmorphologically confirmed from the scanning electron microscopy
data. TG/DSC has been used to study the thermal behaviors of the vari-
ous samples. From optical and electron microscopy studies, it was ob-
served that after firing at 1150 °C, the as-formed uniform compact
green bodies containing combustible pore formers become distorted.
Samples with high density polyethylene as pore former resulted in po-
rous bodies, confirming that the choice of pore formers is critical in
agnifications of (A) 8000× (B) 15,000×.



Plate II. SEM images of beneficiated Kankara kaolin at magnifications of (A) 8000× (B) 15,000×.

Plate III. SEM images of raw Kibi kaolin at magnifications of (A) 8000× (B) 15,000×.

Plate IV. SEM images of beneficiated Kankara kaolin at magnifications of (A) 8000× (B) 15,000×.

202 D.O. Obada et al. / Applied Clay Science 132–133 (2016) 194–204



Table 3
Values of porosity and standard deviation for all samples.

Sample code % P1 % P2 % P3 % P4 % P5 % Pavg SD

A 47.13 47.01 47.12 47.10 47.11 47.09 0.05
B 50.21 50.17 50.15 50.20 50.18 50.18 0.02
C 41.30 41.27 41.21 41.25 41.21 41.24 0.03
D 46.53 46.50 46.51 46.47 46.51 46.50 0.02
E 52.87 52.84 52.87 52.81 52.84 52.85 0.02
F 67.13 67.10 67.12 67.11 67.10 67.11 0.01
G 28.63 28.61 28.63 28.60 28.61 28.61 0.01

% P1–5 = Percentage porosities of the 5 samples for each batch formulation.
SD = Standard deviation.

203D.O. Obada et al. / Applied Clay Science 132–133 (2016) 194–204
achieving porous ceramic bodies. Formulations containing 80% kaolin
can be used for the production of porous ceramics with porosities as
high as 67% employing the appropriate pore formers for specific
applications.
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	Potentials of fabricating porous ceramic bodies from kaolin for catalytic substrate applications
	1. Introduction
	2. Experimental methods
	2.1. Raw material beneficiation and powder preparation
	2.2. X-ray fluorescence (XRF)
	2.3. XRD analysis and crystallinity index
	2.4. Fourier infrared spectroscopy
	2.5. Thermogravimetry
	2.6. Scanning electron microscopy
	2.7. Formation of porous green bodies

	3. Results and discussion
	3.1. Sieve size analysis
	3.2. XRD patterns and Hinckley index of kaolinite
	3.3. SEM micrographs of Kankara and Kibi kaolin
	3.4. Thermogravimetric behaviour of kaolin samples
	3.5. FTIR analysis
	3.6. Formation of porous green bodies

	4. Conclusions
	References