FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2045620094> ?p ?o ?g. }

• W2045620094 abstract "The interband optical properties of crystalline (quartz) and amorphous ${mathrm{SiO}}_{2}$ in the vacuum ultraviolet (VUV) region have been investigated using combined spectroscopic ellipsometry and VUV spectroscopy. Over the range of 1.5--42 eV the optical properties exhibit similar exciton and interband transitions, with crystalline ${mathrm{SiO}}_{2}$ exhibiting larger transition strengths and index of refraction. Crystalline ${mathrm{SiO}}_{2}$ has more sharp features in the interband transition strength spectrum than amorphous ${mathrm{SiO}}_{2}$, the energy of the absorption edge for crystalline ${mathrm{SiO}}_{2}$ is about 1 eV higher than that for amorphous ${mathrm{SiO}}_{2}$, and the direct band-gap energies for $X$-cut and $Z$-cut quartz are 8.30 and 8.29 eV within the absorption coefficient range $2text{--}20phantom{rule{0.3em}{0ex}}{mathrm{cm}}^{ensuremath{-}1}$. In crystalline ${mathrm{SiO}}_{2}$ we report different interband transition peaks at 16.2, 20.1, 21, 22.6, and 27.5 eV, which are in addition to those lower energy transitions previously reported at 10.4, 11.6, 14, and 17.1 eV. We find the bulk plasmon energy in $X$- and $Z$-cut crystalline quartz and amorphous ${mathrm{SiO}}_{2}$ to be at 24.6, 25.2, and 23.7 eV, respectively. The oscillator strength $(f)$ sum rules of the interband transitions for crystalline ${mathrm{SiO}}_{2}$ is 10--10.8 electrons per formula unit for transition energies up to 45 eV. These differences in the electronic structure and optical properties, and the physical densities of crystalline and amorphous ${mathrm{SiO}}_{2}$, can be attributed to differences in the intermediate-range order (IRO) and long-range order (LRO) of the different forms of ${mathrm{SiO}}_{2}$. The intimate relationship between the electronic structure and optical properties and the London dispersion interaction has attracted increased interest recently, and the role of amorphous silica and other structural glass formers as a fluid in high-temperature wetting and materials processes means a detailed knowledge of the optical properties and London dispersion interaction in ${mathrm{SiO}}_{2}$ is important. Hamaker constants for the London dispersion interaction of the configuration of two layers of $ctext{ensuremath{-}}{mathrm{SiO}}_{2}$ or $atext{ensuremath{-}}{mathrm{SiO}}_{2}$ separated by an interlayer film have been determined, using full spectral methods, from the interband transition strength. The London dispersion interaction is appreciably larger in $ctext{ensuremath{-}}{mathrm{SiO}}_{2}$ than $atext{ensuremath{-}}{mathrm{SiO}}_{2}$ due to the increased physical density, index of refraction, transition strengths, and oscillator strengths in quartz." @default.
• W2045620094 created "2016-06-24" @default.
• W2045620094 creator A5049416926 @default.
• W2045620094 creator A5077396877 @default.
• W2045620094 creator A5082367956 @default.
• W2045620094 creator A5085904418 @default.
• W2045620094 date "2005-11-16" @default.
• W2045620094 modified "2023-10-14" @default.
• W2045620094 title "Optical properties and London dispersion interaction of amorphous and crystalline<mml:math xmlns:mml=http://www.w3.org/1998/Math/MathML display=inline><mml:mrow><mml:msub><mml:mi>SiO</mml:mi><mml:mn>2</mml:mn></mml:msub></mml:mrow></mml:math>determined by vacuum ultraviolet spectroscopy and spectroscopic ellipsometry" @default.
• W2045620094 cites W1643713250 @default.
• W2045620094 cites W1662667408 @default.
• W2045620094 cites W1964842893 @default.
• W2045620094 cites W1969628546 @default.
• W2045620094 cites W1983536964 @default.
• W2045620094 cites W1984433171 @default.
• W2045620094 cites W1987508802 @default.
• W2045620094 cites W1990633469 @default.
• W2045620094 cites W2001610435 @default.
• W2045620094 cites W2009096848 @default.
• W2045620094 cites W2017408836 @default.
• W2045620094 cites W2031061744 @default.
• W2045620094 cites W2033923136 @default.
• W2045620094 cites W2039695828 @default.
• W2045620094 cites W2042174402 @default.
• W2045620094 cites W2045177958 @default.
• W2045620094 cites W2051442345 @default.
• W2045620094 cites W2055155238 @default.
• W2045620094 cites W2061664865 @default.
• W2045620094 cites W2062944301 @default.
• W2045620094 cites W2063656848 @default.
• W2045620094 cites W2064756274 @default.
• W2045620094 cites W2065073135 @default.
• W2045620094 cites W2074439496 @default.
• W2045620094 cites W2078775452 @default.
• W2045620094 cites W2082257264 @default.
• W2045620094 cites W2092140987 @default.
• W2045620094 cites W2093874650 @default.
• W2045620094 cites W2114303209 @default.
• W2045620094 cites W2114494400 @default.
• W2045620094 cites W2117681120 @default.
• W2045620094 cites W2118667615 @default.
• W2045620094 cites W2130447490 @default.
• W2045620094 cites W2149366263 @default.
• W2045620094 cites W2152791335 @default.
• W2045620094 cites W2158660123 @default.
• W2045620094 cites W2159529419 @default.
• W2045620094 cites W2160144133 @default.
• W2045620094 cites W2161685940 @default.
• W2045620094 cites W2169673731 @default.
• W2045620094 cites W2314870378 @default.
• W2045620094 cites W2334396850 @default.
• W2045620094 cites W24419868 @default.
• W2045620094 cites W2498190793 @default.
• W2045620094 cites W2545123082 @default.
• W2045620094 cites W4234497080 @default.
• W2045620094 doi "https://doi.org/10.1103/physrevb.72.205117" @default.
• W2045620094 hasPublicationYear "2005" @default.
• W2045620094 type Work @default.
• W2045620094 sameAs 2045620094 @default.
• W2045620094 citedByCount "89" @default.
• W2045620094 countsByYear W20456200942012 @default.
• W2045620094 countsByYear W20456200942013 @default.
• W2045620094 countsByYear W20456200942014 @default.
• W2045620094 countsByYear W20456200942015 @default.
• W2045620094 countsByYear W20456200942016 @default.
• W2045620094 countsByYear W20456200942017 @default.
• W2045620094 countsByYear W20456200942018 @default.
• W2045620094 countsByYear W20456200942019 @default.
• W2045620094 countsByYear W20456200942020 @default.
• W2045620094 countsByYear W20456200942021 @default.
• W2045620094 countsByYear W20456200942022 @default.
• W2045620094 countsByYear W20456200942023 @default.
• W2045620094 crossrefType "journal-article" @default.
• W2045620094 hasAuthorship W2045620094A5049416926 @default.
• W2045620094 hasAuthorship W2045620094A5077396877 @default.
• W2045620094 hasAuthorship W2045620094A5082367956 @default.
• W2045620094 hasAuthorship W2045620094A5085904418 @default.
• W2045620094 hasConcept C113196181 @default.
• W2045620094 hasConcept C121332964 @default.
• W2045620094 hasConcept C17729963 @default.
• W2045620094 hasConcept C181966813 @default.
• W2045620094 hasConcept C185592680 @default.
• W2045620094 hasConcept C186370098 @default.
• W2045620094 hasConcept C192562407 @default.
• W2045620094 hasConcept C26873012 @default.
• W2045620094 hasConcept C32891209 @default.
• W2045620094 hasConcept C43617362 @default.
• W2045620094 hasConcept C56052488 @default.
• W2045620094 hasConcept C62520636 @default.
• W2045620094 hasConcept C8010536 @default.
• W2045620094 hasConceptScore W2045620094C113196181 @default.
• W2045620094 hasConceptScore W2045620094C121332964 @default.
• W2045620094 hasConceptScore W2045620094C17729963 @default.
• W2045620094 hasConceptScore W2045620094C181966813 @default.
• W2045620094 hasConceptScore W2045620094C185592680 @default.
• W2045620094 hasConceptScore W2045620094C186370098 @default.
• W2045620094 hasConceptScore W2045620094C192562407 @default.
• W2045620094 hasConceptScore W2045620094C26873012 @default.
• W2045620094 hasConceptScore W2045620094C32891209 @default.
• W2045620094 hasConceptScore W2045620094C43617362 @default.

• next