Oxidation state of zirconium and tungsten on a Schottky electron source at high temperature

•We investigated the zirconium coated tungsten surface using X-ray photoemission spectroscopy at greater than 1400 K.•We improved the sample heating system to keep the high temperature while maintaining ultra-high vacuum.•The improved heating system enable us to integrated spectra, and the detailed...

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Bibliographic Details
Published in:Surface science 2021-05, Vol.707, p.121802, Article 121802
Main Authors: Matsunaga, Soichiro, Katagiri, Souichi, Kikawa, Takeshi
Format: Article
Language:English
Subjects:
Diffusion coating
Electron sources
Emitters (electron)
Heating
Heating system
High temperature
Operating temperature
Oxidation
Oxygen
Photoelectric emission
Schottky electron sources
Spectrum analysis
Stoichiometry
Surface diffusion
Tungsten
Valence
Work functions
X-ray photoemission spectroscopy
Zirconium
Zirconium oxides
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Summary:•We investigated the zirconium coated tungsten surface using X-ray photoemission spectroscopy at greater than 1400 K.•We improved the sample heating system to keep the high temperature while maintaining ultra-high vacuum.•The improved heating system enable us to integrated spectra, and the detailed chemical shifts can be discussed.•A significant amount of oxygen present on the surface at 1400 K.•We found two kinds of metastable tungsten oxide present on the surface. [Display omitted] We investigated the zirconium-oxide-coated-tungsten (100) surface, which is widely used as the electron-emitting surface in Schottky electron sources. To extract electrons, the emitter is heated to approximately 1800 K. When the surface reaches a temperature greater than 1400 K, the work function of the (100) surface is selectively lowered by the coating of zirconium and oxygen, and surface diffusion of the atoms is rapid on the tungsten surface. The mechanism behind this process, however, is not clear because it is difficult to analyze the surface at high temperatures. In this study, we resolved this issue by improving our sample heating system and investigated the zirconium and oxygen-coated tungsten (100) surface using X-ray photoemission spectroscopy at 1500 K. The stable heating system helped us acquire highly reliable spectra, enabling us to elucidate the detailed bonding state of the atoms on the surface. We also found that a large amount of oxygen is present on the surface even at high operating temperatures. Moreover, zirconium and tungsten are partially oxidized, and the stoichiometry of these oxides is distinctly different from that of the stable oxide within the bulk.
ISSN:0039-6028
1879-2758
DOI:10.1016/j.susc.2021.121802