Transient Structures of PdO during CO Oxidation over Pd(100)

Shipilin, Mikhail; Gustafson, Johan; Zhang, Chu; Merte, Lindsay R.; Stierle, Andreas; Hejral, Uta; Ruett, Uta; Gutowski, Olof; Skoglundh, Magnus; Carlsson, Per-Anders; Lundgren, Edvin

doi:10.1021/acs.jpcc.5b04400

Cited by 43 publications

(79 citation statements)

References 31 publications

(70 reference statements)

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“…These changes were explained as the possible formation of incommensurate structures or as CO bonded to Pt steps or kinks. Although CO seems to increase the mobility of Pt atoms at the step and induce the formation of kink sites, 55,58,59 large-scale roughening of the Pt (111) surface in CO was not observed at a pressure of around 100 kPa.…”

Section: Pt(111) Co Adsorptionmentioning

confidence: 92%

“…It is believed to use both physisorbed and precursor states. 19 After dissociation, the O atoms are separated by two lattice constants on the Pt (111) surface, thus requiring a large surface area to dissociatively adsorb, 20 whereas CO needs only a single free site to adsorb.…”

Section: Joost W M Frenkenmentioning

confidence: 99%

“…The epitaxial oxide had a thickness of 5 AE 2 nm and an island width of approximately 47 AE 1 nm. 112 It coexisted with the surface oxide thus showing a Stranski-Krastanov, i.e., layerplus-island, growth mode. Additional structural information on the transition from a reduced to an oxidized surface can be obtained from a reported work combining HP STM and QMS.…”

mentioning

confidence: 98%

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Surface science under reaction conditions: CO oxidation on Pt and Pd model catalysts

2017

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Platinum and palladium are frequently used as catalytic materials, for example for the oxidation of CO. This is one of the most widely studied reactions in the field of surface science. Although seemingly uncomplicated, it remains an active and interesting topic, which is partially explained by the push to conduct experiments on model systems under relevant reaction conditions. Recent developments in the surface-science methodology have allowed obtaining chemical and structural information on the active phase of model catalysts. Tools of the trade include near-ambient-pressure X-ray photoelectron spectroscopy, high-pressure scanning tunneling microscopy, high-pressure surface X-ray diffraction, and high-pressure vibrational spectroscopy. Interpretation is often aided by density functional theory in combination with thermodynamic and kinetic modeling. In this review, results for the catalytic oxidation of CO obtained by these techniques are compared. On several of the Pt and Pd surfaces, new structures develop in excess O 2 . For Pt, this requires a much larger excess of O 2 than for Pd. Most of these structures also develop in pure O 2 and are identified as (surface) oxides. A large body of evidence supports the conjecture that these oxides are more reactive than the corresponding O-covered metallic surfaces under similar conditions, although still debated in the literature. An outlook on this developing field, including directions that move away from CO oxidation towards more complex chemistry, concludes this review.

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Section: Pt(111) Co Adsorptionmentioning

confidence: 92%

Section: Joost W M Frenkenmentioning

confidence: 99%

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Surface science under reaction conditions: CO oxidation on Pt and Pd model catalysts

2017

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“…Approaches Using High Energy (>50 keV): SXRD and Total X-ray Scattering/PDF High energy scattering methods are also coming of age, as hopefully the study shown in Section 2.7 has made clear in the case of supported Pt catalysts for fast PDF studies. However, SXRD [177,178] made upon metal surfaces and a sophisticated variant of it due to Stierle and co-workers [179][180][181][182] using high energy X-rays to investigate supported nanoparticles has much to offer; and there are good reasons to think that in the near future both high energy PDF, XRD and even high energy SAXS measurements are going to be able to play ever more important roles in the wider scheme of catalytic science.…”

Section: Saxs and Gisaxsmentioning

confidence: 99%

Time Resolved Operando X-ray Techniques in Catalysis, a Case Study: CO Oxidation by O2 over Pt Surfaces and Alumina Supported Pt Catalysts

Newton

2017

Catalysts

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Abstract:The catalytic oxidation of CO by O 2 to form CO 2 over Pt surfaces and supported catalysts is one of the most studied catalytic reactions from both fundamental and applied points of view. This review aims to show how the application of a range of time resolved, X-ray based techniques, such as X-ray diffraction (XRD), Surface X-ray diffraction (SXRD), total X-ray scattering/pair distribution function (PDF), X-ray absorption (XAFS), X-ray emission (XES), and X-ray photoelectron spectroscopies (XPS), applied under operando conditions and often coupled to adjunct techniques (for instance mass spectrometry (MS) and infrared spectroscopy (IR)) have shed new light on the structures and mechanisms at work in this most studied of systems. The aim of this review is therefore to demonstrate how a fusion of the operando philosophy with the ever augmenting capacities of modern synchrotron sources can lead to new insight and catalytic possibilities, even in the case of a process that has been intensely studied for almost 100 years.

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“…Surface oxides rather than surfaces covered by chemisorbed oxygen have been 35 observed as the most active towards CO oxidation under near ambient as well as more realistic 36 conditions (above ambient pressure) [5][6][7][8][9][10][11][12][13][14][15][16]. However, some studies also indicate Pd surfaces covered 37 by atomic oxygen as highly active [8,17], and generally both will exhibit activity.…”

Section: Introductionmentioning

confidence: 99%

Near Ambient Pressure XPS Investigation of CO Oxidation Over Pd3Au(100)

et al. 2017

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19The CO oxidation behavior under excess oxygen and near stoichiometric conditions over the surface 20 of Pd3Au(100) has been studied by combining near-ambient pressure X-ray photoelectron 21 spectroscopy and quadrupole mass spectrometry and compared to Pd(100). During heating and 22 cooling cycles, normal hysteresis in the CO2 production, i.e. with the light-off temperature being 23 higher than the extinction temperature, is observed for both surfaces. On both Pd3Au(100) and 24Pd(100) the (√5x√5)R27° surface oxide structure is present during CO2 production under excess 25 oxygen conditions (O2:CO = 10:1), while at near stoichiometric conditions (O2:CO = 1:1) the surfaces 26 are covered with atomic oxygen. Au as alloying element hence induces only minor differences in the 27 observed hysteresis and the active phase compared to pure Pd. Alloying with Au thus yields a 28 different behavior compared to Ag, where reversed hysteresis is observed for CO2 production over 29 Pd75Ag25(100) at similar conditions [Fernandes et al., ACS Catal. (2016)

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Transient Structures of PdO during CO Oxidation over Pd(100)

Cited by 43 publications

References 31 publications

Surface science under reaction conditions: CO oxidation on Pt and Pd model catalysts

Surface science under reaction conditions: CO oxidation on Pt and Pd model catalysts

Time Resolved Operando X-ray Techniques in Catalysis, a Case Study: CO Oxidation by O2 over Pt Surfaces and Alumina Supported Pt Catalysts

Near Ambient Pressure XPS Investigation of CO Oxidation Over Pd3Au(100)

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