FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2002191130> ?p ?o ?g. }

• W2002191130 endingPage "1492" @default.
• W2002191130 startingPage "1491" @default.
• W2002191130 abstract "Molecular beam techniques have been used to study the dissociative chemisorption of oxygen on W(110). Chemisorption probabilities have been measured as a function of incidence angle, θi kinetic energy, Ei , and of surface coverage and temperature. In addition, angular scattering distributions have been measured for a range of conditions, and LEED has been used to examine surface structure. Sticking probabilities are determined as a function of coverage from the time dependence of reflected beam intensities, using Auger electron spectroscopy and LEED to calibrate the surface coverage. The initial (zero coverage limit) sticking probability is found to depend strongly on the incidence energy, scaling with En=Ei cos2 θi . This probability is ∼10% at En=0.1 eV, rising to essentially unity above En=0.4 eV. In most cases, the sticking probability is found to fall roughly linearly with increasing surface coverage. However, a less rapid falloff is observed for En≥1 eV and for En≤0.03 eV; the sticking probability actually rises with increasing coverage, reaching a maximum at ∼0.2 ML. For En≤0.3 eV, the chemisorption probability falls to &lt;3% for a coverage of ∼0.5 ML; however, this apparent saturation coverage rises in a smooth step to 0.75 ML at ∼0.25 eV and to ∼1.0 ML in another step centered at ∼0.85 eV. These ‘‘favored’’ coverages of 0.5, 0.75, and 1.0 ML are found to be associated with p(2×1), p(2×2), and p(1×1) LEED patterns, respectively. Angular scattering distributions recorded with a differentially pumped rotatable mass spectrometer revealed predominantly quasispecular peaks. The energy dependence of the sticking probability and the observed falloff of the sticking probability with increasing coverage are not compatible with a classical precursor model, although such a process may indeed dominate for near-zero incidence energies at low surface temperatures." @default.
• W2002191130 created "2016-06-24" @default.
• W2002191130 creator A5003685354 @default.
• W2002191130 creator A5046827479 @default.
• W2002191130 creator A5049857121 @default.
• W2002191130 date "1986-05-01" @default.
• W2002191130 modified "2023-10-16" @default.
• W2002191130 title "Molecular beam study of the dissociative chemisorption of oxygen on W(110)" @default.
• W2002191130 doi "https://doi.org/10.1116/1.573550" @default.
• W2002191130 hasPublicationYear "1986" @default.
• W2002191130 type Work @default.
• W2002191130 sameAs 2002191130 @default.
• W2002191130 citedByCount "10" @default.
• W2002191130 crossrefType "journal-article" @default.
• W2002191130 hasAuthorship W2002191130A5003685354 @default.
• W2002191130 hasAuthorship W2002191130A5046827479 @default.
• W2002191130 hasAuthorship W2002191130A5049857121 @default.
• W2002191130 hasConcept C113196181 @default.
• W2002191130 hasConcept C121332964 @default.
• W2002191130 hasConcept C135889238 @default.
• W2002191130 hasConcept C147789679 @default.
• W2002191130 hasConcept C150394285 @default.
• W2002191130 hasConcept C162711632 @default.
• W2002191130 hasConcept C178790620 @default.
• W2002191130 hasConcept C184779094 @default.
• W2002191130 hasConcept C185544564 @default.
• W2002191130 hasConcept C185592680 @default.
• W2002191130 hasConcept C25442681 @default.
• W2002191130 hasConcept C2779758070 @default.
• W2002191130 hasConcept C2780646311 @default.
• W2002191130 hasConcept C32909587 @default.
• W2002191130 hasConcept C33790079 @default.
• W2002191130 hasConcept C43617362 @default.
• W2002191130 hasConcept C54419926 @default.
• W2002191130 hasConcept C62520636 @default.
• W2002191130 hasConcept C9950777 @default.
• W2002191130 hasConceptScore W2002191130C113196181 @default.
• W2002191130 hasConceptScore W2002191130C121332964 @default.
• W2002191130 hasConceptScore W2002191130C135889238 @default.
• W2002191130 hasConceptScore W2002191130C147789679 @default.
• W2002191130 hasConceptScore W2002191130C150394285 @default.
• W2002191130 hasConceptScore W2002191130C162711632 @default.
• W2002191130 hasConceptScore W2002191130C178790620 @default.
• W2002191130 hasConceptScore W2002191130C184779094 @default.
• W2002191130 hasConceptScore W2002191130C185544564 @default.
• W2002191130 hasConceptScore W2002191130C185592680 @default.
• W2002191130 hasConceptScore W2002191130C25442681 @default.
• W2002191130 hasConceptScore W2002191130C2779758070 @default.
• W2002191130 hasConceptScore W2002191130C2780646311 @default.
• W2002191130 hasConceptScore W2002191130C32909587 @default.
• W2002191130 hasConceptScore W2002191130C33790079 @default.
• W2002191130 hasConceptScore W2002191130C43617362 @default.
• W2002191130 hasConceptScore W2002191130C54419926 @default.
• W2002191130 hasConceptScore W2002191130C62520636 @default.
• W2002191130 hasConceptScore W2002191130C9950777 @default.
• W2002191130 hasIssue "3" @default.
• W2002191130 hasLocation W20021911301 @default.
• W2002191130 hasOpenAccess W2002191130 @default.
• W2002191130 hasPrimaryLocation W20021911301 @default.
• W2002191130 hasRelatedWork W1967151310 @default.
• W2002191130 hasRelatedWork W1995357258 @default.
• W2002191130 hasRelatedWork W2002191130 @default.
• W2002191130 hasRelatedWork W2003716745 @default.
• W2002191130 hasRelatedWork W2025470355 @default.
• W2002191130 hasRelatedWork W2029863829 @default.
• W2002191130 hasRelatedWork W2042273721 @default.
• W2002191130 hasRelatedWork W2057066643 @default.
• W2002191130 hasRelatedWork W2057481332 @default.
• W2002191130 hasRelatedWork W2153012392 @default.
• W2002191130 hasVolume "4" @default.
• W2002191130 isParatext "false" @default.
• W2002191130 isRetracted "false" @default.
• W2002191130 magId "2002191130" @default.
• W2002191130 workType "article" @default.