The C1s core line in irradiated graphite

Recently, plasma deposited amorphous carbon films have been the subject of extensive experimental and theoretical investigations aimed at correlating their electronic, structural, and mechanical properties to growth parameters. To investigate these properties, different spectral parameters reflectin...

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Published inJournal of applied physics Vol. 102; no. 4
Main Authors Speranza, Giorgio, Minati, Luca, Anderle, Mariano
Format Journal Article
LanguageEnglish
Published United States 15.08.2007
Subjects
AMORPHOUS STATE
ARGON IONS
CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY
CRYSTAL GROWTH
ELECTRICAL PROPERTIES
ELECTRONIC STRUCTURE
GRAPHITE
ION BEAMS
IRRADIATION
MECHANICAL PROPERTIES
OXIDATION
X-RAY PHOTOELECTRON SPECTROSCOPY
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Abstract Recently, plasma deposited amorphous carbon films have been the subject of extensive experimental and theoretical investigations aimed at correlating their electronic, structural, and mechanical properties to growth parameters. To investigate these properties, different spectral parameters reflecting the electronic structure of carbon-based materials are proposed in literature. The effects of various electronic configurations on the carbon photoelectron spectra are analyzed here with particular attention to C1s core line with the aim to better interpret its structure. The latter is commonly fitted under the assumption that it can be described by using just two spectral components related to sp2 and sp3 hybrids. Their relative intensities are then used to estimate the sp2 and sp3 phases. We show that, in the presence of an amorphous network, the C1s line shape is the result of a more complex mixture of electronic states. Ar+ irradiated graphite and successive oxidation was used to identify spectral features to better describe the C1s line shape.
AbstractList Recently, plasma deposited amorphous carbon films have been the subject of extensive experimental and theoretical investigations aimed at correlating their electronic, structural, and mechanical properties to growth parameters. To investigate these properties, different spectral parameters reflecting the electronic structure of carbon-based materials are proposed in literature. The effects of various electronic configurations on the carbon photoelectron spectra are analyzed here with particular attention to C1s core line with the aim to better interpret its structure. The latter is commonly fitted under the assumption that it can be described by using just two spectral components related to sp2 and sp3 hybrids. Their relative intensities are then used to estimate the sp2 and sp3 phases. We show that, in the presence of an amorphous network, the C1s line shape is the result of a more complex mixture of electronic states. Ar+ irradiated graphite and successive oxidation was used to identify spectral features to better describe the C1s line shape.
Recently, plasma deposited amorphous carbon films have been the subject of extensive experimental and theoretical investigations aimed at correlating their electronic, structural, and mechanical properties to growth parameters. To investigate these properties, different spectral parameters reflecting the electronic structure of carbon-based materials are proposed in literature. The effects of various electronic configurations on the carbon photoelectron spectra are analyzed here with particular attention to C1s core line with the aim to better interpret its structure. The latter is commonly fitted under the assumption that it can be described by using just two spectral components related to sp{sup 2} and sp{sup 3} hybrids. Their relative intensities are then used to estimate the sp{sup 2} and sp{sup 3} phases. We show that, in the presence of an amorphous network, the C1s line shape is the result of a more complex mixture of electronic states. Ar{sup +} irradiated graphite and successive oxidation was used to identify spectral features to better describe the C1s line shape.
Author Minati, Luca
Anderle, Mariano
Speranza, Giorgio
Author_xml – sequence: 1
  givenname: Giorgio
  surname: Speranza
  fullname: Speranza, Giorgio
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  givenname: Luca
  surname: Minati
  fullname: Minati, Luca
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  givenname: Mariano
  surname: Anderle
  fullname: Anderle, Mariano
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Snippet Recently, plasma deposited amorphous carbon films have been the subject of extensive experimental and theoretical investigations aimed at correlating their...
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Index Database
SubjectTerms AMORPHOUS STATE
ARGON IONS
CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY
CRYSTAL GROWTH
ELECTRICAL PROPERTIES
ELECTRONIC STRUCTURE
GRAPHITE
ION BEAMS
IRRADIATION
MECHANICAL PROPERTIES
OXIDATION
X-RAY PHOTOELECTRON SPECTROSCOPY
Title The C1s core line in irradiated graphite
URI https://www.osti.gov/biblio/21057500
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