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Sains Malaysiana 37(2): 201-203(2008)
Synthesis and Characterisation of Tris(1-carboxyl-2-phenyl-1,2-ethyleno dithiolenic-S,S’) Tungsten Complex as Photocatalyst for Photolysis of H2O Molecules (Sintesis dan Pencirian Kompleks Tris[1-karboksil-2-fenil-1,2-etilenoditiolenik-S,S’] Tungsten sebagai Fotomangkin untuk Fotolisis Molekul H2O)
Fadhli Hadana Rahman, Rusli Daik & Mohammad Kassim School of Chemical Sciences and Food Technology Faculty of Science and Technology, Universiti Kebangsaan Malaysia 43600 UKM Bangi, Selangor, Malaysia
Khuzaimah & Wan Ramli Wan Daud Department of Chemical and Process Engineering Faculty of Engineering, Universiti Kebangsaan Malaysia 43600 UKM Bangi, Selangor, Malaysia
Received: 4 April 2007 / Accepted: 13 July 2007
ABSTRACT
Tris(1-carboxyl-2-phenyl-1,2-ethylenodithiolenic-S,S’) tungsten complex is one of the most promising photocatalyst to be used in photolysis of water to produce hydrogen. The first step of the synthesis involves a metathesis reaction of tetrapropylammonium bromide [{(C3H7)4N}Br] and ammonium tetrathiotungstate [(NH4)2WS4] to form a tetrapropylammonium tetrathiotungstate [{(C3H7)4N}2WS4] (precursor). Then, the precursor was reacted with phenylacetylenecarboxylic acid (C9H6O2) to form tris(1-carboxyl-2-phenyl-1,2-ethylenodithiolenic-S,S’) tungsten complex (C27H18O2S6W). The infra-red, ultra violet/visible (UV/Vis) spectrum, nuclear magnetic resonance (NMR) and elemental micro-analysis of C, H, N and S agreed with the characteristic of the tris(1-carboxyl-2-phenyl-1,2-ethylenodithiolenic-S,S’) tungsten complex. The (W-S), (C-S) and (C=O) stretching frequencies were detected at 511, (1470 and 1035) and 1655 cm-1, respectively. The 1H NMR spectrum showed six protons in the complex. The 13C NMR showed only 7 signals for carbon atom in the benzene ring, ethylene groups and carboxylic acid pendant group due to the symmetry of the molecules. The reaction yield was about 50 percent. Photolysis of acetone spiked H2O showed that the catalyst was able to produced 1.8µmol/h hydrogen.
Keywords: dye-sensitised solar cell; hydrogen; photolysis; sunlight; tungsten
ABSTRAK
Kompleks tris(1-karboksil-2-fenil-1,2-etilenoditiolenik-S,S’) tungsten merupakan salah satu daripada kompleks yang berpotensi tinggi untuk digunakan bagi proses fotolisis air untuk menghasilkan gas hidrogen. Langkah pertama sintesis melibatkan tindak balas metatesis di antara tetrapropilammonium bromida [{(C3H7)4N}Br] dan ammonium tetratiotungstat [(NH4)2WS4] untuk menghasilkan tetrapropilammonium tetratiotungstat [{(C3H7)4N}2WS4] (prekursor). Seterusnya prekusor bertindak balas dengan asid fenilasetilenakarboksilik (C9H6O2) dan membentuk kompleks tris(1-karboksil-2-fenil-1,2-etilenoditiolenik-S,S’) tungsten (C27H18O2S6W). Molekul telah diciri dengan kaedah spketroskopi inframerah (IR), ultraviolet/boleh nampak (UV/Vis), resonans magnet nuklear (NMR) dan analisis-mikro unsur C, H, N dan S. Spektrum IR menunujukkan kehadiran frekuensi regangan (W-S), (C-S) dan (C=O) masing-masing pada 511, (1470 dan 1035) dan 1655 cm-1. Spektrum NMR 1H menunjukkan kehadiran 6 proton kumpulan propil dan spektrum NMR 13C hanya menunujukkan 7 atom C bagi gelang benzena, etilena dan asid karbosilik. Hanya bilangan setara isyarat resonans 1H dan 13C dikesan kerana struktur mempunyai satah simetri yang tinggi. Peratus hasil kompleks agak rendah (50%) disebabkan kesukaran untuk memisahkan isomer yang terbentuk. Ujian fotolisis air yang dicampur aseton memnunjukkan kemampuan fotomangkin untuk menghasilkan hidrogen pada kadar 1.8µmol/j.
Kata kunci: bahan pewarna-pemeka sel solar; hidrogen; fotolisis; sinaran matahari; tungsten
RUJUKAN/REFERENCES
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