Quantum Yield of Formaldehyde Formation in the Presence of Colloidal TiO2-Based Photocatalysts:  Effect of Intermittent Illumination, Platinization, and Deoxygenation

Colloidal TiO2 (2.4 nm average particle diameter) has been prepared and modified by photodeposition of Pt (PtTi-S1) and by mixing with Pt nanoparticles (PtTi-S2). Transmission electron microscopy reveals particle aggregation in colloidal TiO2 and large networks of agglomerated particles in the plati...

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Published in:The journal of physical chemistry. B 2004-09, Vol.108 (37), p.14082-14092
Main Authors: Wang, Chuan-yi, Pagel, Ronald, Bahnemann, Detlef W, Dohrmann, Jürgen K
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creator Wang, Chuan-yi
Pagel, Ronald
Bahnemann, Detlef W
Dohrmann, Jürgen K
description Colloidal TiO2 (2.4 nm average particle diameter) has been prepared and modified by photodeposition of Pt (PtTi-S1) and by mixing with Pt nanoparticles (PtTi-S2). Transmission electron microscopy reveals particle aggregation in colloidal TiO2 and large networks of agglomerated particles in the platinized samples. The photocatalytic activity of the samples (0.1 g L-1) has been investigated by measuring the quantum yield, φ HCHO, of HCHO formed from aqueous methanol at pH 3.5 under different conditions. In CW photolysis of the oxygenated suspensions (300−400 nm UV light, 8 × 10-7 einstein L-1 s-1 photon absorption rate) the platinized photocatalysts (1 wt % Pt) enhance φ HCHO by a factor of 1.5−1.7 with respect to neat colloidal TiO2 where φ HCHO is 0.02. In addition to the action of Pt as an electron sink, the strong promotion of photocatalytic methanol oxidation by PtTi-S2 at the small Pt/TiO2 particle ratio of ca. 1:1060 is proposed to arise from transfer of excitation energy or of photogenerated charge carriers through the particle network. Repetitive laser-pulse illumination of the oxygenated samples (351 nm, 0.5 Hz repetition frequency) increases φ HCHO by ca. 50% in comparison with CW illumination at the same average photon absorption rate of ca. 8 × 10-7 einstein L-1 s-1. As a tentative explanation an increase of the photocatalyst surface by laser-pulse stimulated deaggregation of colloidal TiO2 and fragmentation of the networks in the platinized samples is suggested. HCHO is also produced in the deoxygenated suspensions under repetitive laser-pulse illumination. PtTi-S1 and PtTi-S2 increase φ HCHO by factors of 1.8 and 1.2, respectively, in comparison with neat colloidal TiO2 where φ HCHO is 0.027. Possible mechanisms are discussed. The higher activity of PtTi-S1 is attributed to stronger electrocatalysis of H2 formation by highly dispersed Pt in PtTi-S1 as compared with the Pt particles in PtTi-S2.
doi_str_mv 10.1021/jp048046s
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Transmission electron microscopy reveals particle aggregation in colloidal TiO2 and large networks of agglomerated particles in the platinized samples. The photocatalytic activity of the samples (0.1 g L-1) has been investigated by measuring the quantum yield, φ HCHO, of HCHO formed from aqueous methanol at pH 3.5 under different conditions. In CW photolysis of the oxygenated suspensions (300−400 nm UV light, 8 × 10-7 einstein L-1 s-1 photon absorption rate) the platinized photocatalysts (1 wt % Pt) enhance φ HCHO by a factor of 1.5−1.7 with respect to neat colloidal TiO2 where φ HCHO is 0.02. In addition to the action of Pt as an electron sink, the strong promotion of photocatalytic methanol oxidation by PtTi-S2 at the small Pt/TiO2 particle ratio of ca. 1:1060 is proposed to arise from transfer of excitation energy or of photogenerated charge carriers through the particle network. Repetitive laser-pulse illumination of the oxygenated samples (351 nm, 0.5 Hz repetition frequency) increases φ HCHO by ca. 50% in comparison with CW illumination at the same average photon absorption rate of ca. 8 × 10-7 einstein L-1 s-1. As a tentative explanation an increase of the photocatalyst surface by laser-pulse stimulated deaggregation of colloidal TiO2 and fragmentation of the networks in the platinized samples is suggested. HCHO is also produced in the deoxygenated suspensions under repetitive laser-pulse illumination. PtTi-S1 and PtTi-S2 increase φ HCHO by factors of 1.8 and 1.2, respectively, in comparison with neat colloidal TiO2 where φ HCHO is 0.027. Possible mechanisms are discussed. 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In addition to the action of Pt as an electron sink, the strong promotion of photocatalytic methanol oxidation by PtTi-S2 at the small Pt/TiO2 particle ratio of ca. 1:1060 is proposed to arise from transfer of excitation energy or of photogenerated charge carriers through the particle network. Repetitive laser-pulse illumination of the oxygenated samples (351 nm, 0.5 Hz repetition frequency) increases φ HCHO by ca. 50% in comparison with CW illumination at the same average photon absorption rate of ca. 8 × 10-7 einstein L-1 s-1. As a tentative explanation an increase of the photocatalyst surface by laser-pulse stimulated deaggregation of colloidal TiO2 and fragmentation of the networks in the platinized samples is suggested. HCHO is also produced in the deoxygenated suspensions under repetitive laser-pulse illumination. PtTi-S1 and PtTi-S2 increase φ HCHO by factors of 1.8 and 1.2, respectively, in comparison with neat colloidal TiO2 where φ HCHO is 0.027. 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B</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Wang, Chuan-yi</au><au>Pagel, Ronald</au><au>Bahnemann, Detlef W</au><au>Dohrmann, Jürgen K</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Quantum Yield of Formaldehyde Formation in the Presence of Colloidal TiO2-Based Photocatalysts:  Effect of Intermittent Illumination, Platinization, and Deoxygenation</atitle><jtitle>The journal of physical chemistry. B</jtitle><addtitle>J. Phys. Chem. B</addtitle><date>2004-09-16</date><risdate>2004</risdate><volume>108</volume><issue>37</issue><spage>14082</spage><epage>14092</epage><pages>14082-14092</pages><issn>1520-6106</issn><eissn>1520-5207</eissn><abstract>Colloidal TiO2 (2.4 nm average particle diameter) has been prepared and modified by photodeposition of Pt (PtTi-S1) and by mixing with Pt nanoparticles (PtTi-S2). Transmission electron microscopy reveals particle aggregation in colloidal TiO2 and large networks of agglomerated particles in the platinized samples. The photocatalytic activity of the samples (0.1 g L-1) has been investigated by measuring the quantum yield, φ HCHO, of HCHO formed from aqueous methanol at pH 3.5 under different conditions. In CW photolysis of the oxygenated suspensions (300−400 nm UV light, 8 × 10-7 einstein L-1 s-1 photon absorption rate) the platinized photocatalysts (1 wt % Pt) enhance φ HCHO by a factor of 1.5−1.7 with respect to neat colloidal TiO2 where φ HCHO is 0.02. In addition to the action of Pt as an electron sink, the strong promotion of photocatalytic methanol oxidation by PtTi-S2 at the small Pt/TiO2 particle ratio of ca. 1:1060 is proposed to arise from transfer of excitation energy or of photogenerated charge carriers through the particle network. Repetitive laser-pulse illumination of the oxygenated samples (351 nm, 0.5 Hz repetition frequency) increases φ HCHO by ca. 50% in comparison with CW illumination at the same average photon absorption rate of ca. 8 × 10-7 einstein L-1 s-1. As a tentative explanation an increase of the photocatalyst surface by laser-pulse stimulated deaggregation of colloidal TiO2 and fragmentation of the networks in the platinized samples is suggested. HCHO is also produced in the deoxygenated suspensions under repetitive laser-pulse illumination. PtTi-S1 and PtTi-S2 increase φ HCHO by factors of 1.8 and 1.2, respectively, in comparison with neat colloidal TiO2 where φ HCHO is 0.027. Possible mechanisms are discussed. The higher activity of PtTi-S1 is attributed to stronger electrocatalysis of H2 formation by highly dispersed Pt in PtTi-S1 as compared with the Pt particles in PtTi-S2.</abstract><pub>American Chemical Society</pub><doi>10.1021/jp048046s</doi><tpages>11</tpages></addata></record>
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title Quantum Yield of Formaldehyde Formation in the Presence of Colloidal TiO2-Based Photocatalysts:  Effect of Intermittent Illumination, Platinization, and Deoxygenation
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