Selective Catalytic Ammonia Oxidation to Nitrogen by Atomic Oxygen Species on Ag(111)

Karatok, Mustafa; Vovk, Evgeny I.; Koç, Ali; Özensoy, Emrah

doi:10.1021/acs.jpcc.7b08291

Cited by 22 publications

(15 citation statements)

References 73 publications

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“…The dissociation of oxygen was believed to be the rate-controlling step for ammonia oxidation, while low surface coverage favors N 2 formation. Similar conclusions were given by Karatok et al [85] The exposure of ozone on Ag(111) surfaces at −133 • C led to a disordered surface atomic oxygen overlayer (confirmed by LEED). Such oxygen species selectively catalyzed N-H bond cleavage, yielding mostly N 2 and minor amounts of by-products (NO and N 2 O).…”

Section: Ag-based Catalystssupporting

confidence: 88%

Progress on Noble Metal-Based Catalysts Dedicated to the Selective Catalytic Ammonia Oxidation into Nitrogen and Water Vapor (NH3-SCO)

Jabłońska

2021

Molecules

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A recent development for selective ammonia oxidation into nitrogen and water vapor (NH3-SCO) over noble metal-based catalysts is covered in the mini-review. As ammonia (NH3) can harm human health and the environment, it led to stringent regulations by environmental agencies around the world. With the enforcement of the Euro VI emission standards, in which a limitation for NH3 emissions is proposed, NH3 emissions are becoming more and more of a concern. Noble metal-based catalysts (i.e., in the metallic form, noble metals supported on metal oxides or ion-exchanged zeolites, etc.) were rapidly found to possess high catalytic activity for NH3 oxidation at low temperatures. Thus, a comprehensive discussion of property-activity correlations of the noble-based catalysts, including Pt-, Pd-, Ag- and Au-, Ru-based catalysts is given. Furthermore, due to the relatively narrow operating temperature window of full NH3 conversion, high selectivity to N2O and NOx as well as high costs of noble metal-based catalysts, recent developments are aimed at combining the advantages of noble metals and transition metals. Thus, also a brief overview is provided about the design of the bifunctional catalysts (i.e., as dual-layer catalysts, mixed form (mechanical mixture), hybrid catalysts having dual-layer and mixed catalysts, core-shell structure, etc.). Finally, the general conclusions together with a discussion of promising research directions are provided.

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Section: Ag-based Catalystssupporting

confidence: 88%

Progress on Noble Metal-Based Catalysts Dedicated to the Selective Catalytic Ammonia Oxidation into Nitrogen and Water Vapor (NH3-SCO)

Jabłońska

2021

Molecules

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“…The first state is the low-coverage α 1 state, which has a desorption maximum at 279 K. With an increasing θ NH 3 , the α 1 state starts to broaden toward lower temperatures. The second submonolayer desorption state which is denoted as α 2 starts to appear around 0.6 MLE and reaches its desorption maximum around 164 K. A further increase in θ NH 3 leads to the formation of the α 3 111), 44 Au(111), 45 Pt(111), 46 Ag(111), 47 Ni(111), 48 and Ru(0001). 49 The broadening of the TPD signals in Figure 1 toward low temperatures can be explained by the presence of the repulsive interactions between the adsorbed ammonia molecules on Pd(111) and the existence of dissimilar adsorption sites and adsorption configurations.…”

Section: Resultsmentioning

confidence: 99%

Enhancement of Formic Acid Dehydrogenation Selectivity of Pd(111) Single Crystal Model Catalyst Surface via Brønsted Bases

2019

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The influence of ammonia (NH 3) on the doubly deuterated formic acid (DCOOD, FA) dehydrogenation selectivity for a Pd(111) single crystal model catalyst surface was investigated under ultrahigh vacuum conditions using temperature-programmed desorption and temperatureprogrammed reaction spectroscopy techniques. NH 3 adsorption on Pd(111) revealed reversible, molecular desorption without any significant decomposition products, while DCOOD adsorption on Pd(111) yielded D 2 , D 2 O, CO, and CO 2 as a result of dehydration and dehydrogenation pathways. Functionalizing the Pd(111) surface with ammonia suppressed the FA dehydration and enhanced the dehydrogenation pathway. The boost in the FA dehydrogenation of Pd(111) in the presence of NH 3 can be linked to the ease of FA deprotonation as well as the stabilization of the decomposition intermediate (i.e., formate) due to the presence of ammonium counterions on the surface. In addition, the presence of a Hbonded ammonia network on the Pd(111) surface increased the hydrogen atom mobility and decreased the activation energy for molecular hydrogen desorption. In the presence of NH 3 , catalytic FA decomposition on Pd(111) also yielded amidation reactions, which further suppressed CO liberation and prevented poisoning of the Pd(111) active sites due to strongly bound CO species.

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“…In former studies, oxygen coverage for a single layer of silver oxide with various oxide structures [i.e., p(4 × 4), p(4 × 5r3)] was calculated to be 0.375 ML. 13 Thus, in the current work, the saturation oxygen coverage obtained at the top layer of Ag(111) in the oxygen TPD experiments 35 was assumed to be 0.375 ML and used as a reference.…”

Section: ■ Introductionmentioning

confidence: 99%

Formaldehyde Selectivity in Methanol Partial Oxidation on Silver: Effect of Reactive Oxygen Species, Surface Reconstruction, and Stability of Intermediates

et al. 2021

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Selective oxidation reactions on heterogeneous silver catalysts are essential for the mass production of numerous industrial commodity chemicals. However, the nature of active oxygen species in such reactions is still debated. To shed light on the role of different oxygen species, we studied the methanol oxidation reaction on Ag(111) single-crystal model catalyst surfaces containing two dissimilar types of oxygen (electrophilic, O e and nucleophilic, O n ). X-ray photoelectron spectroscopy and low energy electron diffraction experiments suggested that the atomic structure of the Ag(111) surface remained mostly unchanged after accumulating low O e coverage at 140 K. Temperature-programmed reaction spectroscopic investigation of low coverages of O e on Ag(111) revealed that O e was active for methanol oxidation on Ag(111) with a high selectivity toward formaldehyde (CH 2 O) production. High surface oxygen coverages, on the other hand, triggered a reconstruction of the Ag(111) surface, yielding Ag oxide domains, which catalyzes methanol total oxidation to CO 2 and decreases the formaldehyde selectivity. This important finding indicates a trade-off between CH 2 O selectivity and methanol conversion, where 93% CH 2 O selectivity can be achieved for an oxygen surface coverage of θ O = 0.08 ML (ML = monolayer) with moderate methanol conversion, while methanol conversion could be boosted by a factor of ∼4 for θ O = 0.26 ML with a suppression of CH 2 O selectivity to 50%. Infrared reflection absorption spectroscopy results and density functional theory calculations indicated that Ag oxide contains dissimilar adsorption sites for methoxy intermediates, which are also energetically less stable than that of the unreconstructed Ag(111). The current findings provide important molecular-level insights regarding the surface structure of the oxidized Ag(111) model catalyst directly governing the competition between different reaction pathways in methanol oxidation reaction, ultimately dictating the reactant conversion and product selectivity.

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Selective Catalytic Ammonia Oxidation to Nitrogen by Atomic Oxygen Species on Ag(111)

Cited by 22 publications

References 73 publications

Progress on Noble Metal-Based Catalysts Dedicated to the Selective Catalytic Ammonia Oxidation into Nitrogen and Water Vapor (NH3-SCO)

Progress on Noble Metal-Based Catalysts Dedicated to the Selective Catalytic Ammonia Oxidation into Nitrogen and Water Vapor (NH3-SCO)

Enhancement of Formic Acid Dehydrogenation Selectivity of Pd(111) Single Crystal Model Catalyst Surface via Brønsted Bases

Formaldehyde Selectivity in Methanol Partial Oxidation on Silver: Effect of Reactive Oxygen Species, Surface Reconstruction, and Stability of Intermediates

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