Enhancement of the ETS-10 Titanosilicate Activity in the Shape-Selective Photocatalytic Degradation of Large Aromatic Molecules by Controlled Defect Production

Xamena, Françesc X. Llabrés i; Calza, Paola; Lamberti, Carlo; Prestipino, Carmelo; Damin, Alessandro; Bordiga, Silvia; Pelizzetti, Ezio; Zecchina, Adriano

doi:10.1021/ja027382o

Cited by 150 publications

(94 citation statements)

References 36 publications

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“…1, 18 On the other hand, the use of an active support (under UV-Vis conditions), such as titania or a titano-silicate (Ti-SiO 2 ), is an available strategy to enhance the catalytic activity of the final catalytic system. 22,23 In the present work, Pd and Co x Pd 1-x NPs were prepared by the well-established procedure of the reduction by solvent method using PVP as capping agent and following an already reported procedure. 15,24 After their purification, the NPs were loaded on SiO 2 and Ti-SiO 2 (UV-Vis inactive and active supports, respectively) to study their catalytic activity in AB Fig.…”

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confidence: 99%

Enhanced ammonia-borane decomposition by synergistic catalysis using CoPd nanoparticles supported on titano-silicates

et al. 2016

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The decomposition of small molecules (such as formic acid or ammonia-borane (AB)) is one of the most promising alternatives for the in-situ H 2 generation towards a H 2 scenario implementation. 1-3 AB is claimed as one of the inorganic compounds with the highest hydrogen content (19.6 H 2 wt. %). This, added to its high reactivity with noble metals (such as Ru, Pd or Pt) makes it one of the best candidates for its use as H 2 feed in a PEMFC. [3][4][5][6][7][8] The total decomposition of this compound in liquid phase using water as solvent produces 3 mol of H 2 per mol of AB according to the following reaction equation.Ammonia borane is a liquid-phase chemical hydrogen storage material with great current interest. Its decomposition on a wide range of catalysts has been extensively reported in the literature. Among these, noble metals such as Rh, Ir, Ru, and Pt, have shown interesting catalytic activities, 10 but they are unsuitable for widespread practical applications due to their availability and price. Previous studies have demonstrated that bimetallic nanoparticles combining a noble metal and a firstrow transition metal forming an alloy structure could be promising candidates for the design of catalysts for the hydrolysis of ammonia borane. 11In order to assess the beneficial effect of these noble metal/first-row transition metal combinations for this application, we have used Pd due to its moderate activity among noble metals 12 and Co because it shows the highest activity among non-noble metal catalysts. 11,13,14The enhancement of the catalytic activity of the supported noble metal can be attained by different routes; i) increasing the metal dispersion on the support by the synthesis of very small NPs, 15 ii) alloying the noble metal with a transition metal, (which is also attractive due to the cost reduction of the catalysts) 11,16,17 and iii) supporting the NPs on an UV-Vis active support to upgrade the electron-transfer from the support to the NPs. 1,18 In the present study, the synthesis of Pd and Co-PdNPs by the reduction-by-solvent methodology has been applied with successful results in the production of H 2 by AB decomposition. The synthesis conditions allow a perfect control over size and morphology of the NPs (both mono-and bimetallic). Pure or alloyed cobalt (as oxide or reduced form) has been addressed in the recent literature as a promising metal in the AB decomposition reaction due to its low cost (compared with noble metals) and its high activity in relevant reactions. 12,16,[19][20][21] Due to their different reduction potential (compared with Pd), when M-Pd (i. e. Cu or Co) are wellalloyed there is a charge transfer from the M to Pd increasing the electron density on the Pd atom and its activity in the AB decomposition is enhanced. 1,18 On the other hand, the use of an active support (under UV-Vis conditions), such as titania or a titano-silicate (Ti-SiO 2 ), is an available strategy to enhance the catalytic activity of the final catalytic system. 22,23In the present work, Pd and Co x Pd 1-x...

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Enhanced ammonia-borane decomposition by synergistic catalysis using CoPd nanoparticles supported on titano-silicates

et al. 2016

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“…The first centers on tailoring of the size, shape, and threedimensional organization of TiO 2 particles [1,2,11,12] or of Ti-O-Ti wires with semiconductor character. [5,[13][14][15][16] The second strategy focuses on improving the photocatalytic properties: i) by incorporating metal cations and anions (mainly nitrogen, sulphur, iodine, and other elements) into the bulk; [6,14,[17][18][19][20][21][22][23] ii) by supporting metal particles (mainly Au, Ag, Pt, Ni). [1,3,[24][25][26][27][28][29][30][31] Interesting results are obtained when the two abovementioned research directions are combined to benefit from the sum of their advantages.…”

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Oriented TiO₂ Nanostructured Pillar Arrays: Synthesis and Characterization

Cesano¹,

Bertarione²,

Damin³

et al. 2008

Advanced Materials

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TiO 2 with tailored porosity, particle size, and shape in the nanometer range is attracting a lot of attention because of its potential use in photocatalysis and energy conversion. As far as photocatalysis applications are concerned, the use of high surface area TiO 2 as a photocatalyst for pollutant degradation and for water splitting is of particular interest. [1][2][3][4][5][6][7] The presence of bulk defects and grain boundary barriers-associated with the small dimensions of the particles, recombination of electrons, and holes generated by band-gap excitation-is limiting the photoconversion efficiency. [8][9][10] To improve charge separation and the associated catalytic efficiency, researchers have essentially followed two strategies. The first centers on tailoring of the size, shape, and threedimensional organization of TiO 2 particles [1,2,11,12] or of Ti-O-Ti wires with semiconductor character. [5,[13][14][15][16] The second strategy focuses on improving the photocatalytic properties: i) by incorporating metal cations and anions (mainly nitrogen, sulphur, iodine, and other elements) into the bulk; [6,14,[17][18][19][20][21][22][23] ii) by supporting metal particles (mainly Au, Ag, Pt, Ni). [1,3,[24][25][26][27][28][29][30][31] Interesting results are obtained when the two abovementioned research directions are combined to benefit from the sum of their advantages. [32] Several strategies have been adopted for the development of energy conversion applications in solar cells. [1,3,[33][34][35][36] Among them, the use of dye-sensitized TiO 2 nanostructures has an outstanding reputation and both experimental and theoretical evaluations of the efficiency-limiting factors have been identified. [33,37,38] Recently, it has been shown that the use of ordered arrays of TiO 2 nanostructures (either pure, such as nanotubes, nanowires, and nanorods [39][40][41] or TiO 2 -based architectures, [15,42,43] which replace the traditional nanoparticle film) can improve the efficiency. [9,34,40,[43][44][45][46][47][48][49] Moreover, it is evident from recent literature data [1,3,9,44,50] that the innovative synthesis of TiO 2 particle arrays, either pure or anchored to conducting substrates, plays a leading role in both photocatalysis and energy conversion applications.In this paper, we describe a new method for the synthesis of parallelly aligned TiO 2 micropillars, either pure or fixed to a rigid carbon support. Accurate characterization shows that, depending upon the synthesis conditions, the micropillars constitute of partially cemented pure anatase or a mixture of coexisting anatase and rutile particles with a diameter in the 10-20 nm range. The obtained materials combine high surface areas ($60 m 2

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“…While microporous ETS-4 and ETS-10 exhibit significant selectivity in the photodegradation of various molecules using both UV and visible lights, TiO 2 (P25) selectivity is observed with visible light only. This means that besides the inverse shape-selectivity effect already observed for the microporous materials [132], selectivity may be achieved also by selecting the excitation light in accordance with the electronic transition of the adsorbed molecule. In such a case, the photodegradation may occur if the conduction band of the Ti-based material is opportunely matched with the lowest unoccupied molecular orbital (LUMO) level of the adsorbed molecule so that it can receive the electron of the excited adsorbate (concept of band alignment).…”

Section: Fields Of Applicationsmentioning

confidence: 92%

“…The classic example is the use of the microporous titanosilicate ETS-10 [131,132]. The photoactivated ETS-10 shows catalytic activity driven by the size and polarity of the substrates.…”

Section: Fields Of Applicationsmentioning

confidence: 99%

Environmental Catalysis over Zeolites

Centi¹,

Perathoner²

2010

Zeolites and Catalysis

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Enhancement of the ETS-10 Titanosilicate Activity in the Shape-Selective Photocatalytic Degradation of Large Aromatic Molecules by Controlled Defect Production

Cited by 150 publications

References 36 publications

Enhanced ammonia-borane decomposition by synergistic catalysis using CoPd nanoparticles supported on titano-silicates

Enhanced ammonia-borane decomposition by synergistic catalysis using CoPd nanoparticles supported on titano-silicates

Oriented TiO₂ Nanostructured Pillar Arrays: Synthesis and Characterization

Environmental Catalysis over Zeolites

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Enhancement of the ETS-10 Titanosilicate Activity in the Shape-Selective Photocatalytic Degradation of Large Aromatic Molecules by Controlled Defect Production

Cited by 150 publications

References 36 publications

Enhanced ammonia-borane decomposition by synergistic catalysis using CoPd nanoparticles supported on titano-silicates

Enhanced ammonia-borane decomposition by synergistic catalysis using CoPd nanoparticles supported on titano-silicates

Oriented TiO2 Nanostructured Pillar Arrays: Synthesis and Characterization

Environmental Catalysis over Zeolites

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Oriented TiO₂ Nanostructured Pillar Arrays: Synthesis and Characterization