Photocatalytic decomposition of isolan black by tio2, tio2 sio2 core shell nanocomposites

IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
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Volume: 02 Issue: 09 | Sep-2013, Available @ http://www.ijret.org 46
PHOTOCATALYTIC DECOMPOSITION OF ISOLAN BLACK BY TIO2,
TIO2-SIO2 CORE SHELL NANOCOMPOSITES
K. Balachandran1
, R. Venckatesh2
, Rajeshwari Sivaraj3
1
Department. of Chemistry, Vivekanandha College of Engineering for Women, Tiruchengode-637 205, Tamilnadu, India,
2
Department of Chemistry, Government Arts College, Udumalpet, Tamilnadu, India
3
Department of Biotechnology, Karpagam University, Coimbatore, Tamilnadu, India,
balanano06@gmail.com, rvenckat@gmail.com, rajs@gmail.com
Corresponding Author: K. Balachandran
Abstract
Anatase phase TiO2, TiO2-SiO2 (TS) photocatalyst were prepared by wet chemical technique. The synthesized nano particles were
characterized by XRD, SEM-EDAX, TEM, UV and FTIR spectroscopy. The grain size of the TiO2 nanoparticles was found to be 24nm,
while 7-10nm for TiO2-SiO2was calculated by using Scherrer’s formula. The TiO2-SiO2 core shell nanocomposites were identified by
TEM analysis. Ti-O, Si-O bonds were confirmed by EDAX and FTIR. The photocatalytic decomposition of Isolan black was
investigated. The photo catalytic activity of TiO2, enhanced by doping of SiO2 on TiO2. The important factors such as pH, Wt % of
dyes and nanoparticles, intensity of light are also affect the photocatalytic action.
Index Terms: Nanocomposites, Photocatalyst, TEM, SEM-EDAX.
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1. INTRODUCTION
The waste water that is characterized with high colour, high
COD, low biodegradability and high variability has seriously
polluted the drain water. Among the problems it causes colour.
The most critical dye stuff is the primary source of colour.
Most of the dye stuffs are complicated aromatic compounds
and are chemically stable. Through the waste water posses the
low BOD/COD ratio, colour, COD and residual dye level are
still high even after traditional biological treatment or
chemical coagulation treatment. Without further treatment the
waste water will not meet the ever stricter environmental
standards of discharged water.
Many processes have been proposed over the years and are
currently used to remove organic toxins from waste water.
Current treatment methods for these contaminants such as
adsorption by activated carbon and air stripping, merely
concentrate the chemicals present by transferring them to the
adsorbent or air, but they do not convert them into non toxic
wastes. Thus one of the major advantages of the photo
catalytic process over existing technologies is that there is no
further requirement for secondary disposal methods [1].
During the photo catalytic process, the illumination of a
semiconductor photocatalyst with ultraviolet radiation
activates the catalyst, establishing a redox environment in the
aqueous solution [2]. Semiconductors act as sensitizers for
light induced redox process due to their electronic structure,
which is characterized by a filled valence band and an empty
conduction band [3]. The energy difference between the
valence band and conduction band is called bandgap.
Nanocrystalline photo catalysts are ultra small semiconductor
particles which are few nanometers in size. During the past
decade, the photochemistry of nano semiconductor particles
originates from their unique photophysical and photocatalytic
properties [4]. Due to their large surface area, nano sized
catalyst particles show a significantly enhanced reactivity
compared to larger particles or bulk material.
Heterogenous photocatalysis a promising technology in
environmental cleanup is mostly based on the semiconductor
photocatalyst nanocrystalline TiO2 [5], because it is nontoxic,
easy to be made, inexpensive and chemically stable [6-8].
Photooxidation by using TiO2 photocatalyst is being widely
studied as a relatively new technique of pollution abatement.
TiO2 is a commonly used photocatalyst because of its stability
in UV light and water [9].
Furthermore to improve the efficiency of the catalytic activity
more emphasis is placed on mixing TiO2 with SiO2 [10]. The
addition of SiO2 helps to create new catalytic active sites due
to interaction between TiO2 and SiO2 [10-13]. By introducing
SiO2 on TiO2 can transform amorphous phase to crystalline
anatase phase [14]. Titania-Silica mixed oxides have a large
number of applications in catalysis either as catalyst by
themselves or as catalyst support [15]. TiO2-SiO2 mixed
oxides shows a higher thermal stability, adsorption capability
and good redox properties [16]. A number of methods have
been applied to prepare TiO2-SiO2 composites, including e

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beam evaporation, chemical vapor deposition flame hydrolysis
and sol-gel method. Among all type of synthesis methods
Solgel method has several advantages good homogeneity, ease
of composition control, low processing temperature, ability to
fabricate large area coatings and low equipment cost [17]. The
size and shapes are also modified by Solgel techniques. This
technique can be employed for development of optical
coatings and wave guides [18].
In this present work we synthesis TiO2, TiO2-SiO2 core shell
nanocomposites by Solgel method at room temperature. The
composite was analyzed for grain size by XRD, surface
morphology and composition by SEM-EDAX, band gap by
UV-visible spectra, metal oxide bonds by FT-IR spectra and
the photocatalytic decomposition studies of Isolan black was
investigated by UV-Visible spectroscopy.
2. EXPERIMENTAL
2.1. MATERIALS
All reagents used were of analytical grade purity and were
procured from Merck Chemical Reagent Co. Ltd. India.
2.2 PREPARATION OF NANOCOMPOSITES
In the synthesis of TiO2 particles, Titanium tetra isopropoxide
was used as a precursor and it was mixed with HCl, ethanol
and deionised water mixture, stirred for half an hour, in pH
range of 1.5. 10 ml of deionised water was added to the above
mixture and stirred for 2 hours at room temperature. Finally
the solution was dried at room temperature and the powder
was heated at 120oC for 1 hour. Silica particles were prepared
from silicic acid and were stirred with THF for 1 hour. Then
Titania gel was slowly added to the silica particles. The
mixture was stirred for 3 hours and dried at room temperature.
Finally the mixture was heated at 120oC for 1 hour.
2.3 CHARACTERIZATION
The prepared Nano particles were characterized for the
crystalline structure using D8 Advance X-ray diffraction meter
(Bruker AXS, Germany) at room temperature, operating at 30
kV and 30 mA, using CuKα radiation (λ = 0.15406 nm). The
crystal size was calculated by Scherrer’s formula. Surface
morphology was studied by using SEM-EDS (Model JSM
6390LV, JOEL, USA), UV–Vis diffuse reflectance spectra
were recorded with a Carry 5000 UV-Vis-NIR
spectrophotometer (Varian, USA) and FTIR spectra were
measured on an AVATAR 370-IR spectrometer (Thermo
Nicolet, USA) with a wave number range of 4000 to 400 cm−1
.
2.4 PHOTOCATALYTIC STUDIES
Photocatalytic activity of the as-prepared particles for the
environmental application was evaluated by measuring the
photo degradation of methylene blue (MB) in water under
sunlight irradiation. The initial concentration of MB was
50mgl-1
and the concentration of nanoparticles was 1.0g l-1
.
3. RESULT AND DISCUSSION
Fig.1 shows the XRD patterns of sol-gel derived TiO2 and
nano TiO2-SiO2 composites. The crystallite type of the TS
nano composite particles was the pure anatase. The most
intense reflection at 2θ =25.3o is assigned to anatase (d101).
Not much difference has been detected between patterns of
TiO2 and TiO2–SiO2. The powders showed the crystalline
pattern and the observed d-lines match the reported values for
the anatase phase. The intensity of reflections appeared to be
decreased for TiO2–SiO2 as compared to TiO2 due to inclusion
of amorphous SiO2. The average crystallite size was
determined by carrying slow scan of the powders in the range
24–27o
with the step of 0.01omin–1 from the Scherrer’s
equation using the (101) reflections of the anatase phase
assuming spherical particles. An estimate of the grain size (G)
from the broadening of the main (101) anatase peak can be
done by using the Scherrer’s formula
G = 0.9λ Δ(2θ) cos θ (1)
Where λ is the Cu Kα radiation wavelength and Δ(2θ) is peak
width at half-height. The nanocrystallite sizes were found to
be 15–20nm for TiO2 while 7–10 nm for TiO2–SiO2 powders.
The weakening and broadening of the XRD peaks may be
attributed to the decrease of the sample grain size and the
increase of the SiO2 content. The introduction of SiO2 can
effectively suppress the grain growth of anatase compared
with pure TiO2. Moreover, the suppression is more remarkable
with the introduction of higher silica content, which is
consistent with the literature [19]. The major differences were
the narrower first maximum and the broader second
maximum.

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Fig1. XRD patterns of TiO2, TiO2-SiO2 nano composites.
Fig.2 represents the FT-IR spectra of sol-gel derived TiO2,
TiO2-SiO2 composites. The peaks at 3400 and 1650 cm−1
in
the spectra are due to the stretching and bending vibration of
the -OH group. In the spectrum of pure TiO2, the peaks at 550
cm-1
shows stretching vibration of Ti-O and peaks at 1450 cm-
1
show stretching vibrations of Ti-O-Ti .The spectrum of TiO2-
SiO2 show the peaks at 1400cm-1
, 450-550cm- 1
exhibiting
stretching modes of Ti-O-Ti, 1100cm-1
shows Si-O-Si bending
vibrations and peak at 950cm-1
shows Si-O-Ti vibration modes
which is due to the overlapping from vibrations of Si-OH and
Si-O-Ti bonds. This result indicates that the TS nano particles
were prepared by a combination of TiO2 with SiO2 nano
particles [20].
Fig2. FTIR patterns of TiO2, TiO2-SiO2 nano composites
Fig.3 shows the SEM images along with the particle size
distribution of the pure TiO2 sols and of the colloidal TS nano
composites respectively. The pure TiO2 particles exhibited
irregular morphology due to the agglomeration of primary
particles and with an average diameter of 15-20nm. On the
other hand, the colloidal TS nanocomposites exhibited regular
morphology, since the TiO2 cores were coated by SiO2
particles. The average particle size of the colloidal TS nano
composites was measured to be 7 -10nm. The EDAX analysis
of TiO2, TiO2-SiO2 nano composites confirms the presence of
Ti-O, Si-O bonds.
Fig3: SEM-EDAX analysis of TiO2, TiO2-SiO2 nano
composites.
Fig.4 represents the TEM images of TiO2 and nano TiO2-SiO2
core shell nano composites. Transmission electron
microscopic analysis strongly supported the nanophase
formation of TiO2 and nano TiO2-SiO2 core shell nano
composites. The average particle size measured from TEM
was found to be in the range of 15-20 nm for TiO2, and 10-15
nm for TS, which was slightly varied from the particle size
evaluated from diffraction method since in X-ray analysis it
was assumed that the crystallites are formed without any local
strain. From the TEM scale it was clearly observed that the
particles exhibited in spherical in shape and in nanometer size.
Fig 4b clearly shows the formation of TiO2-SiO2 core shell
nano composites.

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Fig.4 TEM analysis of TiO2, Figure 3f) TEM analysis of
TiO2-SiO2 core shell nano composites
UV–Vis absorption spectra of composite after drying show a
good transparency between 400 and 800 nm (Fig.5). Actually,
the band edge of bulk anatase is ≈3.2 eV and is also shown on
the same graph. After heat treatment, a small modification was
observed, due to the presence of anatase nano crystallites.
Indeed, the gel was highly transparent, and any absorbance
which appeared at energies below the band gap energy was a
result of interference fringes and of the high refraction index
of Titania. When Si was present, four additional small peaks
were observed in the absorption corresponding to the 3P2,
3P1, 3P0 and 1D2 manifolds as seen in Fig.4. Furthermore,
presence of SiO2 content results in higher transparency in the
visible region, due to the smaller particle size and higher
dispersity.
Fig.5. UV-Visible spectroscopy of TiO2, TiO2-SiO2 nano
composites
3.1 PHASE ANALYSIS
The gel-derived specimen obtained after being thermally
treated at 823 K for 6 h were all non-crystalline as evidenced
by XRD analysis. It is known that at about 823 K the
equilibrium phase should be cristobalite for SiO2 and anatase
for TiO2. Accordingly, it is suggested that TiO2 and SiO2 be
mixed uniformly at the atomic scale in the sol-gel conversion
may occur simultaneously; however, one of them would be the
dominant process at the given conditions. Continuous
proceeding of the condensation reaction causes the chain-like
structures to have a fast interaction between unreacted ORÿ
groups and form interchain bonding, which increases the
strength of gel structure. Heat treatment will collapse the
structures of the resultant cross-linked gels, resulting in the
formation of particles with irregular shape, wider particle size
distribution and low specific surface area .The monomers
obtained interact with each other to establish a three
dimensional network structure via condensation and form
solids with textures like fragments of monolith Although heat
treatment spheroidize these fragments, the calcined particles
give a high specific surface areas, due to residual voids in the
network structures Then, the monomers of M(OH)z react with
each other to form particle-like polymers The specific surface
areas of these materials after heat treatment are low since the
hydrogen bonding between the particles makes the particles
pack more efficiently [19].
3.2 FORMING MECHANISM OF STABLE PURE
TIO2 AND SIO2-MODIFIED TIO2 HYDROSOLS
Titania is a Lewis acidic oxide [21]. For pure TiO2 hydrosol,
in the hydrolysis process, Ti(OH)4 was formed after Titanium
tetra isopropoxide was hydrolyzed by ethanol and deionised
water mixture. In the acid-peptization process, a certain
amount of HCl, was added and in the neutralization process,
the added –OH first neutralized the extensive free H+
in the
mixture and later attacked Ti–OH+2.
Ti –OH + H+
 Ti-OH+2
(2)
The pure TiO2 colloid particle can be illustrated as below. For
SiO2-modified TiO2 hydrosols, Ti–O–Si bonds were formed as
indicated from FTIR. The model proposed by Tanabe et al.
[22] assumes that the doped cation enters the lattice of its host
and retains its original coordination number. Since the doped
cation is still bonded to the same number of oxygen, even
though the oxygen atoms have a new coordination number, a
charge imbalance is created. The charge imbalance must be
satiated, so Lewis sites and Brönsted sites are formed when
the charge imbalance is positive and negative, respectively.
The charge imbalance is calculated for each individual bond to
the doped cation and multiplied by the number of bonds to the
cation. SiO2 is tetrahedrally coordinated with each oxygen
atom bonded to two silicon atoms.TiO2 is octahedrally
coordinated with each oxygen atom bonded to three titanium

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atoms. Since the radius of Si4+
is much smaller than that of
Ti4+
, the Ti4+
could be substituted with Si4+
, and Ti–O–Si
bonds were formed. If a silicon atom enters a Titania lattice,
each of its four bonds is now attached to an oxygen having 4/6
anion bond. The charge imbalance is 4× (1−4/6) =+4/3. Since
the imbalance is positive, Lewis sites are formed and more
hydroxyl groups would be absorbed on the colloid core of
TiO2–SiO2 [23].
3.3 DEGRADATION OF DYES
Fig 6, 7 shows the degradation of Isolan black by TiO2, TiO2-
SiO2 composites respectively. The UV-Visible spectra of
initial solution and product under sunlight for 5 hr reaction
over TiO2, TiO2-SiO2 samples were recorded to determine
how deeply Isolan black was degraded. The primary
absorption peaks of the dye solution are shows 575nm in the
range of 200-800nm. As the reaction time increases the peaks
disappear gradually and the full spectrum pattern changes
obviously after 5 hr. At the end of the 5th
reaction time there is
no evident absorption peak observed. It indicates that the main
chromophores in the original dye solution are destroyed with
photocatalytic reaction and proves that the Isolan black is
decomposed in the UV/ TiO2 and UV/ TiO2-SiO2 system.
Fig.6. Photo catalytic decomposition of ISOLAN BLACK by
TiO2.
Fig.7. Photo catalytic decomposition of ISOLAN BLACK by
TiO2-SiO2.
CONCLUSIONS
TiO2, TiO2-SiO2 photocatalyst was synthesized by wet
chemical method and its photocatalytic activity on degradation
of textile dyes were tested. TEM images shows the formation
of core shell nano particles. The surface morphology and
photocatalytic activity was modified by SiO2. In 5 hour
reaction time the concentration level of dye solution lowered
down significantly, which indicates TiO2-SiO2 nanocomposite
was effectively degrade the dye molecules.
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Photocatalytic decomposition of isolan black by tio2, tio2 sio2 core shell nanocomposites

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Photocatalytic decomposition of isolan black by tio2, tio2 sio2 core shell nanocomposites