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Sains Malaysiana 44(7)(2015): 1011–1019 Evaluation
on the Photocatalytic Degradation Activity of Reactive Blue 4 using
Pure Anatase Nano-TiO2 (Penilaian
pada Aktiviti
Degradasi Fotopemangkinan daripada Reaktif Blue 4 menggunakan Anatase Nano-TiO2 Tulen) EMY MARLINA
SAMSUDIN1,
SZE
NEE
GOH2,
TA
YEONG
WU2,
TAN
TONG
LING1,
SHARIFAH BEE
ABD. HAMID1
& JOON CHING JUAN2* 1Nanotechnology &
Catalysis Research Centre (NANOCAT), University of Malaya 50603 Kuala Lumpur,
Malaysia 2Laboratory of Applied
Catalysis and Environmental Technology, School of Science, Monash University Malaysia
Campus, 46150 Bandar Sunway, Selangor Darul Ehsan Malaysia Received: 24 November
2014/Accepted: 3 March 2015 ABSTRACT Disposal of dye wastewater
into water streams without treatment endangers human and marine
lives. This work focused on the second largest class of textile
dyes after azo dyes due to its high resistivity to biodegradation
and high toxicity. The photocatalytic degradation of Reactive Blue
4 (RB4), an anthraquinone
dye, has been investigated using pure anatase
nano titanium (IV) oxide (TiO2).
The dye molecules were fully degraded and the addition of hydrogen
peroxide (H2O2)
enhanced the photodegradation efficiency.
It is found that the degradation as the hydroxyl radicals in the
bulk solution is sufficient for complete mineralisation.
The disappearance of the dye follows pseudo-first-order kinetics.
The effect of pH, amount of photocatalyst,
UV-light
intensity, light source and concentration of hydrogen peroxide was
ascertained. Keywords: Anthraquinone dye; hydrogen peroxide; photocatalysis;
textile wastewater; TiO2 ABSTRAK Pembuangan air
sisa pewarna
ke dalam air sungai
tanpa rawatan
membahayakan kehidupan manusia dan marin. Penyelidikan ini memberi tumpuan kepada pewarna tekstil kelas kedua terbesar
selepas pewarna
azo kerana kerintangan yang tinggi untuk biodegradasi
dan ketoksikan
yang tinggi. Degradasi fotopemangkinan daripada
Reaktif Blue 4 (RB4),
satu pewarna
antrakuinon, telah dikaji menggunakan anatase nano-TiO2 tulen. Molekul pewarna diuraikan
sepenuhnya dan
penambahan hidrogen peroksida (H2O2)
meningkatkan kecekapan
fotopemerosotan. Didapati bahawa
degradasi sebagai
radikal hidroksil dalam penyelesaian pukal adalah mencukupi
untuk mineral lengkap.
Kehilangan
pewarna adalah
mengikut kinetik tertib pertama pseudo. Kesan pH, jumlah fotomangkin, keamatan cahaya UV,
sumber cahaya dan
kepekatan hidrogen
peroksida telah ditentukan dalam kajian ini. Kata kunci: Foto
pemangkinan; hidrogen
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