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Engineering, Technology & Applied Science Research Vol. 11, No. 1, 2021, 6740-6744 6740 

 

www.etasr.com Belkham et al.: Elaboration and Physico-Chemical Characterization of the Gibbsite Li(OH)3 Hybrid … 

 

Elaboration and Physico-Chemical Characterization 
of the Gibbsite Li(OH)3 Hybrid Material 

 

Nour-el-Houda Belkham 
Department of Chemical Engineering 

LMPMP Laboratory 
Ferhat Abbas Sétif I University 

Sétif, Algeria 

anisbelkham2002@yahoo.fr 

Djafer Benachour 
Department of Chemical Engineering 

LMPMP Laboratory 
Ferhat Abbas Sétif I University 

Sétif, Algeria 

bendjafer@univ-setif.dz 

Abedaziz Mehamha 
Center of Mineral Technology and 

Plasturgy 
Quebec, Canada 

amehamha@cegepth.qc.ca 

 

 

Abstract-A hybrid material can be defined as a combination of 

two components of different chemical nature. The combination of 

a mineral matrix and organic matter has multiple significance. 

From a chemical point of view, it allows the obtaining of bi-

functional materials that combine the chemical properties of 

their components. The development of new materials with 

specific properties and nanostructured Lamellar Double 

Hydroxides (LDHs) has been widely investigated due to their 

great importance. This study focuses on the development of a 

hybrid material consisting of a matrix of alumina trihydrate 
Al(OH)3 (gibbsite). Previous studies on the synthesis of 

suspension LDHs by lithium salts intercalation in a gibbsite 

matrix were examined, while the obtained samples were 

characterized by different physicochemical methods. 

Keywords-alumina; inorganic compounds; gibbsite; lithium-

salts intercalation; lamellar double hydroxide components  

I. INTRODUCTION  

Nanotechnology has been used for synthesizing various 
polymer nanocomposites and examining their physical and 
chemical properties [1-3]. The presence of nanoparticles in 
polymers improves their mechanical, electrical, and chemical 
properties as it results in bi-functional materials that combine 
the chemical properties of their components. Layered Double 
Hydroxides (LDHs) have attracted considerable interest due to 
their potential applications as selective sorbent medicines [4, 
5], precursors for ceramics [6], and nanocomposite materials 
[7, 8]. Crystalline aluminum hydroxides, such as gibbsite, 
bayerite, and nordstrandite, exhibit properties of intercalation 
matrices for lithium salts [9-12]. The reaction between 
aluminum hydroxides and lithium salts is represented by: 

LinX + 2n Al(OH)3 + qH2O → �LiAl2(OH)6]n X.qH2O 

The most remarkable synthetic procedure is the direct 
intercalation of lithium salts into crystalline Al(OH)3 
polymorphs [13, 14]. Intercalation of inorganic or organic ions 
into gibbsite matrices is used for creating Li/Al LDHs [15-17]. 
Gibbsite is intercalated with lithium cations obtained from 
various lithium salts, which dehydrate readily giving highly 
crystalline intercalates. These crystal structures display highly 
ordered lamellar phases consisting of eclipsed [LiAl2(OH)6]+ 
sheets with sandwichlike layers of intercalated anions [17]. Li 

and Al-X can be prepared using different synthetic approaches. 
The products are obtained by the intercalation of lithium 
cations into the octahedral voids of aluminum hydroxide layers 
of trihydroxides, having anions and water molecules 
incorporated between the layers [18]. The compounds consist 
of layers with [LiAl2(OH)6]+. Xn-anions of [LiAl2(OH)6]nX or 
Xn-anions and water of [LiAl2(OH)6]nX.qH2O are located 
between the layers. Therefore a structural study of these 
intercalation compounds and their synthesis mechanisms is 
very interesting from both theoretical and practical viewpoints.  

This study investigates the physicochemical properties of 
the intercalation of lithium cations and inorganic anions (Cl-, 
NO3-) from [LiAl2(OH)6]nX.qH2O, where X=Cl-, NO3-, into 
gibbsite Al(OH)3, to examine the structural mechanism leading 
to the double hydroxide lamellar intercalated compounds. The 
obtained phases were examined by X-Ray Diffraction (XRD), 
infrared spectroscopy (FTIR), thermogravimetric analysis 
(TG/DTA), and microscopic (SEM) techniques. The results of 
this paper confirm that the Li–Al LDH synthesized by this 
protocol can be compared with the work already published in 
the synthesis of double lamellar hydroxides [1, 9]. In order to 
have a good reinforcement between the load and the matrix 
(already mentioned at the beginning of the introduction), this 
requires interactions between the organic and inorganic phases. 
Such results open up a new route for the synthesis of 
nanocomposites using polymeric entities and layered materials 
[3]. 

II. MATERIALS AND METHODS 

A. Materials 

The alumina trihydrate (Gibbsite) Al(OH)3 powder was 
supplied by DIPROCHIM in Algeria, and its chemical 
composition was defined by the volumetric method. This 
powder consisted of 61.31% Al2O3, 0.64% SiO2, 2.42% CaO, 
0.30% MgO, 0.16% Fe2O3, and up to 34% water. The average 
particle size of this powder was 15µm, with a density of about 
3.106g/cm3. Two fatty acids were used: palmitic acid C16H32O2 
and stearic acid C18H36O2, which had molecular weights of 
256.43g/mol and 284.49g/mol respectively. 

Corresponding author: Nour-el-Houda Belkham



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B. Synthesis of [LiAl2(OH)6]nX.qH2O 

The layered double hydroxide [LiAl2(OH)6]nX.qH2O was 
synthesized using the previously reported method [11, 13, 17, 
19]. In a standard experiment, the intercalation was achieved 
by stirring a suspension of gibbsite in an aqueous solution 
containing a 6-fold molar excess of lithium salts (LiCl, LiBr, or 
LiNO3) at 90°C for 15h, as shown in Figure 1. Samples were 
washed with 5-10ml of deionized water and then dried in an 
oven at 90°C for 1-2h to give samples of idealized 
composition. 

 

 
Fig. 1.  Experimental setup of the gibbsite synthesis by lithium salt: 
1: hotplate, 2: synthesis balloon, 3: refrigerant, 4: nitrogen  gas balloon,  
5: sample after filtration. 

C. Anion Exchange Reactions  

The intercalated fatty acids were stuffed as follows: 7 moles 
of [LiAl2(OH)6]n2OX.qH were added to 4-fold excess of stearic 
or palmitic acid. The mixture was stirred for 48h at room 
temperature in a nitrogen atmosphere. After hustle and bustle, 
the product was isolated by filtration, washed with deionized 
water, and dried in an oven at room temperature for 48h. 

D. Characterization  

The layered double hydroxide [LiAl2(OH)6]nX.qH2O was 
examined in a Siemens D5000 X-ray diffractometer, equipped 
with a graphite monochromator placed between the sample and 
the detector. The X-ray source was a copper anticathode (λCuKα1 
= 1.5406Å), while the beam divergence was limited to 0.2°. 
The diffractograms were recorded between 2° and 70° (90° in 
some cases) 2θ, using an impact of 2° for mounting in grazing 
incidence. The infrared spectrum was examined using a 
NICOLET 5700 spectrometer, employing KBr technical 
dilution (1.5% w/w) on a range of 400-4000cm with a 
resolution of 2cm. Thermogravimetric analysis was carried out 
on a Setaram TG - DTA 85, from 20 to 850°C with a heating 
rate of 5°C/min. Microscopic studies were carried out with an 
E3 Electroscan SEM at 10 to 30kV, which allowed a 
magnification up to 30,000 times. 

III. RESULTS AND DISCUSSION 

A. X-ray Diffractograms of Hybrid Materials 

Figure 2 shows the intensity/angle graph for raw and 
calcinated materials. The raw alumina spectrum has two major 
peaks at 19° and 21°, corresponding to the combination of 

gibbsite and bayerite phases. The other peaks correspond to 
structures and monohydrate forms. The calcinated at 300°C 
material has lower peaks. This is supposed to be the result of 
smaller crystallite domain sizes due to the stacking disorder of 
aluminum hydroxide layers. The diffractograms of the gibbsite 
products, which came from lithium salts intercalation, showed 
new reflections differing from those of the crystalline gibbsite. 
Figure 3 represents the X-ray diffractograms of the LiCl salt 
intercalation in the Al(OH)3 structure. The possibility for 
gibbsite to react with lithium salts has been shown individually 
[20]. The components' intercalation depended on the Al(OH)3 
dispersion and the nature of lithium chloride, while it was also 
limited by the diffusion rate of a layer of the obtained lithium 
chloride. Among the studied lithium halides, LiCl was more 
reactive with Al(OH)3. This halide showed intercalation 
between LiCl and Al(OH)3. The peak at about 14° after 15h 
reaction indicates that gibbsite was transformed into LDH. 
These reflections of LDH were in agreement with those 
reported in [17, 21-22]. Lithium cations were located in the 
octahedral voids of the aluminum hydroxide layer. 

 

 
Fig. 2.  X-ray diffraction (XRD) of crystalline gibbsite and gibbsite 
calcined at 300°C. 

 

Fig. 3.  X-ray diffraction (XRD) of crystalline gibbsite, gibbsite intercaled 
by LiCl, and anionic exchange precursor with fatty acids (stearic acid). 



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The chloride anions are opposite to lithium cations, at 
exactly the midway between the interlayer spaces, in such a 
way that they are partially lied in the holes of hydroxide ions of 
the layers. The X-ray diffractograms contained intense 
reflections with multiple interplanar distances, indicating that 
the structure of the products was lamellar. Analogous studies 
were performed for [LiA12(OH)6]Br- and [LiAI2(OH)6]NO3-. 
Treatment results of [LiAI2(OH)6]Br- and [LiAI2(OH)6]NO3- 
precursors were similar to those of [LiAI2(OH)6]C1-. 

B. Thermogravimetric Analysis 

Figure 4 shows the Differential Thermal Analysis (DTA) 
thermogram for a gibbsite specimen. As it can be observed, the 
gibbsite loses most of its structural water by thermal 
dehydration above 279.23°C with a weight of about 30%. 
Furthermore, the TG-DTA curve gradually varies with 
increasing temperature, indicating that the gibbsite structure 
changes continually upon heating. This change led to the 
formation of several transition alumina phases that are alumina 
of crystallographic structure intermediates between hydrate and 
alumina α [23, 24]. 

 

 
Fig. 4.  TG/DTA curves of raw gibbsite. 

The thermal stability of the lithium salt intercalated into 
gibbsite noted as compounds [LiAl2(OH)6]X where X={Cl, Br, 
NO3} was examined by TG/DTA measurements between 100-
800°C, and these results are depicted in Figure 5.  

 

 
Fig. 5.  TGA and DTG curves of [LiAl2(OH)6]Cl.H2O precursor. 

The TG/DTA curves exhibit two temperature range regions 
at 100-300°C and 300-600°C. The TG curve shows that the 
major weight loss occurred below 300°C. A weight loss of 25% 
below 250°C happened probably due to the loss of water from 
the external surface. This weight loss is indicated by the two 
sharp endothermic peaks seen in the DTA curve at 207.78°C 
and 250.85°C respectively. The second loss of 15% in 
temperatures between 300 and 600°C was attributed to the 
interlamellar water molecule and dehydroxylation of metal 
hydroxide layers [25]. [LiAl2(OH)6]Br.H2O and 
[LiAl2(OH)6]NO3.H2O samples showed the same trends during 
the thermal analysis with an almost identical weight loss rate 
[26]. 

C. Infrared Spectroscopy (FTIR)  

All reactions were carried out in a closed reaction vessel 
with continuous N2 purging. Under such conditions, CO2 likely 
does not dissolve into the samples. The IR spectra of the 
LiX/Al(OH)3 LDH, as depicted in Figure 6, show no CO3- 
characteristics at ∼1400cm−1, indicating no contamination by 
dissolved carbonate from the air during its synthesis. The IR 
spectra show the bands of stretching vibrations of OH groups, 
deformation vibrations of Al-OH and water molecules, and 
stretching vibrations of the Al-O bond of the [LiAl2(OH)6]X 
LDH [27]. The absorption bands that appear at the 500cm-1 
range are attributed to A1-O bond deformation, and a wide 
strip of binding OH water appears at 3500cm-1. Moreover, 
some bands, especially those observed around 1150cm-1, are 
identifiable.  

 

 
Fig. 6.  IR spectra of rough gibbsite and gibbsite intercalated by LiCl salt. 

Figure 7 shows a band between 3550cm-1 and 3300cm-1, 
which is attributed to the OH bond elongation. A band 
appearing at 1650cm-1 corresponds to the OH bond 
deformation, and the one at 750cm-1 corresponds to the Al-OH 
bond deformation. Figure 8 shows the IR spectra of 
LiAl2(OH)6]Br.H2O, [LiAl2(OH)6]NO3.H2O, and the LDHs 
exchanged by fatty acids, which were similar. In these spectra, 
the difference in the intensity decreases. Further bands were 
found at 2920cm-1 corresponding to the C—H bond with 
asymmetric elongation, at 2850cm-1 corresponding to the C—H 
symmetric stretching bond, and at 1720cm-1 and 1190cm-1 
corresponding to the C=O and the C-O bonds. This analysis 
revealed the presence of all the characteristic vibration modes 



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of the double lamellar hydroxide. Furthermore, the absorption 
bands observed at 3500cm-1 and 1600cm-1 were attributed to 
hydroxylated layers of the [Li-Al-Cl] LDH vibration modes in 
the IR spectrum of intercalated LDH, confirming the LiX 
intercalation into the gibbsite. 

 

 
Fig. 7.  IR spectra of gibbsite intercalated by salt and exchanged by stearic 
acid. 

 
Fig. 8.  IR spectra of gibbsite intercaled by Br, NO3 salts and exchanged by 
stearic and palmitic acid. 

D. Scanning Electron Microscopy (SEM)  

Figure 9 shows images obtained by SEM for various raw 
and synthesized materials to obtain an HDL gibbsite, revealing 
a difference in their particle morphology. The second loss of 
15% in temperatures between 300-600°C is attributed to the 
interlamellar water molecule and dehydroxylation of metal 
hydroxide layers [25]. [LiAl2(OH)6]Br.H2O and 
[LiAl2(OH)6]NO3.H2O samples showed the same trends during 
the thermal analysis with an almost identical weight loss rate 
[26]. 

IV. CONCLUSION 

This study aimed at the synthesis and the characterization 
of a gibbsite based double lamellar hydroxide filler, using 
several characterization techniques (XRD, ATG/ATD, FTIR, 
and SEM). The FTIR spectra confirmed the penetration of 
molecules within these matrices. New absorption bands 
appeared for the investigated materials, including synthesized 

and exchanged samples, following the disappearance of the 
characteristic bands, and a decrease in the absorbance of the 
corresponding peaks. Moreover, the thermogravimetric 
analysis (TG/DTA) proved the high thermal stability of all 
materials. Their calcination at high temperatures resulted only 
in their dehydration, thus creating several transition phases. 
The gibbsite seems to intercalate certain lithium salts, while 
halogen anions intercalate within the gibbsite structure. The 
crystalline structure indicated that these materials showed 
lamellar intercalation of [LiAl2(OH)6]+ cations. The main 
contribution of the current research is the elaboration of a 
mineral ceramic by incorporating a fatty acid between its 
layers, thus facilitating the ceramic-polymer interaction. 

 

(a) 

 

(b) 

 

(c) 

 
Fig. 9.  SEM images of (a) gibbsite Li(OH)3, (b) intercalation of the 
lithium salt into gibbsite, and (c) precursor+stearic acid. 

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