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Published byΓιώργος Δασκαλοπούλου Modified over 6 years ago
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Palladium-tin catalysts for the direct synthesis of H2O2 with high selectivity
by Simon J. Freakley, Qian He, Jonathan H. Harrhy, Li Lu, David A. Crole, David J. Morgan, Edwin N. Ntainjua, Jennifer K. Edwards, Albert F. Carley, Albina Y. Borisevich, Christopher J. Kiely, and Graham J. Hutchings Science Volume 351(6276): February 26, 2016 Published by AAAS
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Fig. 1 Microstructural analysis of 3 wt % Pd–2 wt % Sn/TiO2.
Microstructural analysis of 3 wt % Pd–2 wt % Sn/TiO2. (A to D) Representative STEM-HAADF grayscale images and STEM-EELS (RGB) maps of 3 wt % Pd–2 wt % Sn/TiO2 catalysts at the oxidized stage. (E to H) Images and maps as in (A) to (D) for the same catalyst at the oxidized-reduced-oxidized (O-R-O) stage. From the STEM-HAADF images, three distinct supported species are found in both these catalysts: (i) relatively large (i.e., 3 to 10 nm) nanoparticles (white arrows), (ii) smaller clusters on the nanometer or subnanometer scale (white circles), and (iii) continuous film covering the TiO2 support surface. The qualitative elemental distribution of Pd, Sn, and Ti is represented by red, green, and blue, respectively, in the STEM-EELS maps. As shown in (C) and (H), the continuous film mainly contains Sn, which either supports or embeds the smaller Pd-rich species; (D) and (G) show that the larger particles are Pd-Sn alloys. Scale bars in the images and maps represent 1 nm unless noted otherwise. Simon J. Freakley et al. Science 2016;351: Published by AAAS
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Fig. 2 H2O2 direct synthesis and degradation testing of 3 wt % Pd–2 wt % Sn/TiO2.
H2O2 direct synthesis and degradation testing of 3 wt % Pd–2 wt % Sn/TiO2. (A) Effect of reoxidation time under static air at 400°C on H2O2 synthesis and H2O2 degradation activity for 3 wt % Pd–2 wt % Sn/TiO2 catalyst subjected to oxidation-reduction. (B) Sequential H2O2 synthesis reactions over the 3 wt % Pd–2 wt % Sn/TiO2 material after O-R-O treatment. (C) Degradation activity of optimized O-R-O–treated 3 wt % Pd–2 wt % Sn/TiO2 catalyst compared to 2.5 wt % Au–2.5 wt % Pd/TiO2 (8). Experimental conditions are reported in Table 1. Simon J. Freakley et al. Science 2016;351: Published by AAAS
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Fig. 3 Evolution of catalyst through oxidation-reduction-oxidation cycle.
Evolution of catalyst through oxidation-reduction-oxidation cycle. (A) Proposed mechanism for switching off H2O2 hydrogenation by small Pd-rich NPs through a strong metal-support interaction (SMSI). The secondary metal must both form an alloy with Pd and oxidize to form a secondary support (i.e., SnOx) that can encapsulate the relatively small, poorly alloyed, Pd-rich NPs after an O-R-O cycle. This step prevents these NPs from decomposing and hydrogenating the H2O2 product. (B and C) STEM-EELS mapping of a 5 wt % Pd/SnO2 model catalyst at the oxidized (B) and O-R-O (C) stages, showing partial encapsulation of the Pd NP (red) by SnOx (green) after the O-R-O heat treatment cycle. The Sn intensities in the SnO2 support area were deliberately saturated to reveal any relatively weak signals in the particle region. Scale bars, 1 nm. Simon J. Freakley et al. Science 2016;351: Published by AAAS
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