Photoelectron spectroscopy (XPS) and thermogravimetry (TG) of pure and supported rhenium oxides 1. Pure rhenium compounds

Cimino, A.; Angelis, B.A. De; Gazzoli, Delia; Valigi, M.

doi:10.1002/zaac.19804600109

Cited by 69 publications

(33 citation statements)

References 28 publications

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“…Other data demonstrated that ReO 3 is the product of oxidation of Re in Re/γ -Al 2 O 3 catalyst above 400 • C [16]. It was also reported that at or above 300 • C rhenium heptaoxide is the main product of oxidation of Re supported on alumina [15,21] as well as rhenium powder [27] and thin Re films [28]. As can be seen, the interaction of oxygen with Re/γ -Al 2 O 3 catalyst is a complex process and depends mainly on the temperature and the rhenium loading [13,14,16,18,19].…”

Section: Introductionmentioning

confidence: 93%

XPS study of oxidation of rhenium metal on ?-Al2O3 support

Okal

2004

Journal of Catalysis

113

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Section: Introductionmentioning

confidence: 93%

XPS study of oxidation of rhenium metal on ?-Al2O3 support

Okal

2004

Journal of Catalysis

113

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“…[22][23][24] The existence of a Re 5+ species in binary oxides is inconclusive; however, in rhenium-oxide bronzes (e.g. rhenium oxides alloyed other cationic elements), rhenium oxidation states of +4, 5,6 and 7 are all possible.…”

Section: -315mentioning

confidence: 99%

“…Since the 1970s, many XPS studies have been performed to examine the chemical state of rhenium catalyst surfaces; however, due to instrumentation limitations, these studies were performed ex-situ. [14,20,23,[31][32][33][34][35] The problem with ex-situ studies is that the rhenium oxidation states that are measured postreaction can differ substantially from the species that are present in-situ.…”

Section: -315mentioning

confidence: 99%

The Oxidation of Rhenium and Identification of Rhenium Oxides During Catalytic Partial Oxidation of Ethylene: An In-Situ XPS Study

Greiner

Rocha

Johnson

et al. 2014

Zeitschrift Für Physikalische Chemie

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Rhenium is catalytically active for many valuable chemical reactions, and consequently has been the subject of scientific investigation for several decades. However, little is known about the chemical identity of the species present on rhenium surfaces during catalytic reactions because techniques for investigating catalyst surfaces in-situ -such as near-ambient-pressure X-ray photoemission spectroscopy (NAP-XPS) -have only recently become available. In the current work, we present an in-situ XPS study of rhenium catalysts. We examine the oxidized rhenium species that form on a metallic rhenium foil in an oxidizing atmosphere, a reducing atmosphere, and during a model catalytic reaction (i.e. the partial-oxidation of ethylene). We find that, in an oxidizing environment, a Re 2 O 7 film forms on the metal surface, with buried layers of sub-oxides that contain Re 4+ , Re 2+ and Re

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“…The shifts in binding energies between Re4f 7/2 and Re4f 5/2 peaks of Re +4 in ReO 2 and Re +6 in ReO 3 are significant [24]. The authors of [25] have established an exponential dependence of the binding energy on the oxidation state of Re in the compounds NH 4 ReO 4 , Re 2 O 7 , ReO 3 , ReO 2 and metallic Re without consideration of the underlying structures. However, the difference in the positions of the Re4f 7/2 peaks for Re +7 in NH 4 ReO 4 and Re 2 O 7 points out an influence of the structural features on the XPS spectra: in ammonium perrhenate only corner-sharing ReO 4 -tetrahedra exist, in contrast to both corner-sharing ReO 4 -tetrahedra and ReO 6 -octahedra in Re 2 O 7 .…”

Section: Xps Measurementsmentioning

confidence: 99%

Metallic Re–Re bond formation in different MRe2O6 (MFe, Co, Ni) rutile-like polymorphs: The role of temperature in high-pressure synthesis

Mikhailova¹,

Ehrenberg²,

Oswald³

et al. 2009

Journal of Solid State Chemistry

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Keywords: 3d-metal rhenium oxide MRe 2 O 6 Rutile-like structure Polymorphism High-pressure synthesis Re-Re bond Magnetism XPS spectra a b s t r a c t Different polymorphs of MRe 2 O 6 (MQFe, Co, Ni) with rutile-like structures were prepared using highpressure high-temperature synthesis. For syntheses temperatures higher than $1573 K, tetragonal rutile-type structures (P4 2 /mnm) with a statistical distribution of M-and Re-atoms on the metal position in the structure were observed for all three compounds, whereas rutile-like structures with orthorhombic or monoclinic symmetry, partially ordered M-and Re-ions on different sites and metallic Re-Re-bonds within Re 2 O 10 -pairs were found for CoRe 2 O 6 and NiRe 2 O 6 at a synthesis temperature of 1473 K. According to the XPS measurements, a mixture of Re +4 /Re +6 and M 2+ /M 3+ is present in both structural modifications of CoRe 2 O 6 and NiRe 2 O 6 . The low-temperature forms contain more Re +4 and M 3+ than the high-temperature forms. Tetragonal and monoclinic modifications of NiRe 2 O 6 order with a ferromagnetic component at $24 K, whereas tetragonal and orthorhombic CoRe 2 O 6 show two magnetic transitions: below $17.5 and 27 K for the tetragonal and below 18 and 67 K for the orthorhombic phase. Tetragonal FeRe 2 O 6 is antiferromagnetic below 123 K.

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Photoelectron spectroscopy (XPS) and thermogravimetry (TG) of pure and supported rhenium oxides 1. Pure rhenium compounds

Cited by 69 publications

References 28 publications

XPS study of oxidation of rhenium metal on ?-Al2O3 support

XPS study of oxidation of rhenium metal on ?-Al2O3 support

The Oxidation of Rhenium and Identification of Rhenium Oxides During Catalytic Partial Oxidation of Ethylene: An In-Situ XPS Study

Metallic Re–Re bond formation in different MRe2O6 (MFe, Co, Ni) rutile-like polymorphs: The role of temperature in high-pressure synthesis

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