Catalytic Activity and Selectivities of Metal Oxides and Pt/Al2O3 for NH3 Combustion

Hinokuma, Satoshi; Shimanoe, Hiroki; Matsuki, Shun; Kawano, M.; Kawabata, Yusuke; Machida, Masato

doi:10.1246/cl.151031

Cited by 31 publications

(22 citation statements)

References 14 publications

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“…[10][11][12][13] Fewstudies have been devoted to stoichiometric mixtures. [3,14,15] Thus,there is aneed to develop new ammonia combustion systems.…”

mentioning

confidence: 99%

“…[15] The combustion reaction is also easier to sustain for catalytic reaction. [15] The combustion reaction is also easier to sustain for catalytic reaction.…”

mentioning

confidence: 99%

“…One possible way to avoid the aforementioned issues is by stoichiometric catalytic combustion, which has many advantages over conventional non-catalytic combustion as the ignition temperature is decreased and NOx emission is reduced because of the low operating temperature. [15] The combustion reaction is also easier to sustain for catalytic reaction. Herein, we present abottom-up approach to design anovel core-shell nanoparticulate catalyst of ruthenium (Ru) and copper (Cu).…”

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confidence: 99%

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Bottom‐Up Design of a Copper–Ruthenium Nanoparticulate Catalyst for Low‐Temperature Ammonia Oxidation

et al. 2017

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A novel nanoparticulate catalyst of copper (Cu) and ruthenium (Ru) was designed for low-temperature ammonia oxidation at near-stoichiometric mixtures using a bottom-up approach. A synergistic effect of the two metals was found. An optimum CuRu catalyst presents a reaction rate threefold higher than that for Ru and forty-fold higher than that for Cu. X-ray absorption spectroscopy suggests that in the most active catalyst Cu forms one or two monolayer thick patches on Ru and the catalysts are less active once 3D Cu islands form. The good performance of the tuned Cu/Ru catalyst is attributed to changes in the electronic structure, and thus the altered adsorption properties of the surface Cu sites.

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“…[10][11][12][13] Fewstudies have been devoted to stoichiometric mixtures. [3,14,15] Thus,there is aneed to develop new ammonia combustion systems.…”

mentioning

confidence: 99%

“…[15] The combustion reaction is also easier to sustain for catalytic reaction. [15] The combustion reaction is also easier to sustain for catalytic reaction.…”

mentioning

confidence: 99%

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confidence: 99%

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Bottom‐Up Design of a Copper–Ruthenium Nanoparticulate Catalyst for Low‐Temperature Ammonia Oxidation

et al. 2017

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“…Previously, we proposed novel catalytic NH 3 combustion systems that enable low ignition temperatures as well as negligible N 2 O/NO x emissions, 14)16) and reported that the NH 3 combustion activity of metal oxides increases with a decrease in their metaloxygen bond energy. 14) In addition, a novel catalyst, copper oxide (CuO x ) supported on aluminum oxide borates (10Al 2 O 3 ·2B 2 O 3 : 10A2B) with high performance for NH 3 combustion, was successfully prepared. 15) Although CuO x -based catalysts have also been widely studied for the selective oxidation of NH 3 emissions to reduce air pollution, 17), 18) there are no published studies of the catalytic local structures during NH 3 combustion and/or the oxidation reaction over the well-known supported CuO x .…”

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confidence: 99%

Operando XAFS studies of supported copper oxides for catalytic ammonia combustion

Hinokuma

Kawabata

Kiritoshi

et al. 2017

J. Ceram. Soc. Japan

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Local structures around copper oxides (CuO x ) supported on aluminum oxide borates (10A2B) during the NH 3 combustion reaction were studied by operando XAFS. Although CuO x in as-prepared CuO x /10A2B at room temperature can be assigned to CuO, the CuO was partly reduced to Cu 2 O during NH 3 combustion at 400°C. In contrast, CuAl 2 O 4 was formed after thermal aging of CuO x /10A2B at 900°C for 100 h in air, local structures of which were preserved during NH 3 combustion at 600°C.©2017 The Ceramic Society of Japan. All rights reserved.Key-words : Operando XAFS, Supported catalysts, Copper oxides, Ammonia combustion [Received March 31, 2017; Accepted May 3, 2017] In order to elucidate the actual dynamics of catalysis, the investigation of the local structures during catalytic reactions is essential. Recently, operando X-ray absorption fine structure (XAFS) measurements have made dramatic progress for use as a powerful technique to study the local structures of catalysts under reaction conditions. 1)12) Kornienko et al. revealed a molecular model of an amorphous cobalt sulfide catalyzing hydrogen evolution reactions by operando XAFS and Raman. 6) Li et al. developed a novel micro-reactor compatible with operando XAFS and scanning transmission electron microscopy (STEM) observation to obtain complex structural dynamics of nanocatalysts.7) Operando XAFS study of metal oxide catalysts during the watergas shift reaction was prospected by Rodriguez et al., who also reported their partial reduction behavior.11) Doronkin et al. elucidated the local structures of iron-and copper-containing zeolites during the selective catalytic reduction (SCR) of NO x by NH 3 , and finally concluded their catalysis and SCR mechanism from the operando XAFS study.3) Therefore, operando XAFS has a great impact on the study of the actual local structures during catalytic reactions as well as the reaction mechanisms.NH 3 has recently been regarded as a renewable and carbon-free energy source due to its high energy density, 13) but it has problems including high ignition temperature and N 2 O/NO x production, in comparison with fossil fuels. Previously, we proposed novel catalytic NH 3 combustion systems that enable low ignition temperatures as well as negligible N 2 O/NO x emissions, 14) 16) and reported that the NH 3 combustion activity of metal oxides increases with a decrease in their metaloxygen bond energy. 14)In addition, a novel catalyst, copper oxide (CuO x ) supported on aluminum oxide borates (10Al 2 O 3 ·2B 2 O 3 : 10A2B) with high performance for NH 3 combustion, was successfully prepared. 15)Although CuO x -based catalysts have also been widely studied for the selective oxidation of NH 3 emissions to reduce air pollution, 17),18) there are no published studies of the catalytic local structures during NH 3 combustion and/or the oxidation reaction over the well-known supported CuO x . Therefore, in this study, the local structures around Cu in the previously developed CuO x / 10A2B and in the conventional CuO x /Al 2 O 3 under ...

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“…The main body of research into ammonia oxidation is devoted to the ammonia slip reaction from diesel engines where the reaction is operated in an excess of oxygen . Few studies have been devoted to stoichiometric mixtures . Thus, there is a need to develop new ammonia combustion systems.…”

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confidence: 99%

Bottom‐Up Design of a Copper–Ruthenium Nanoparticulate Catalyst for Low‐Temperature Ammonia Oxidation

et al. 2017

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A novel nanoparticulate catalyst of copper (Cu) and ruthenium (Ru) was designed for low‐temperature ammonia oxidation at near‐stoichiometric mixtures using a bottom‐up approach. A synergistic effect of the two metals was found. An optimum CuRu catalyst presents a reaction rate threefold higher than that for Ru and forty‐fold higher than that for Cu. X‐ray absorption spectroscopy suggests that in the most active catalyst Cu forms one or two monolayer thick patches on Ru and the catalysts are less active once 3D Cu islands form. The good performance of the tuned Cu/Ru catalyst is attributed to changes in the electronic structure, and thus the altered adsorption properties of the surface Cu sites.

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Catalytic Activity and Selectivities of Metal Oxides and Pt/Al₂O₃ for NH₃ Combustion

Cited by 31 publications

References 14 publications

Bottom‐Up Design of a Copper–Ruthenium Nanoparticulate Catalyst for Low‐Temperature Ammonia Oxidation

Bottom‐Up Design of a Copper–Ruthenium Nanoparticulate Catalyst for Low‐Temperature Ammonia Oxidation

<i>Operando</i> XAFS studies of supported copper oxides for catalytic ammonia combustion

Bottom‐Up Design of a Copper–Ruthenium Nanoparticulate Catalyst for Low‐Temperature Ammonia Oxidation

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