Isotope Effect on the Infrared Photoluminescence Decay of Interstitial Oxygen Molecules in Amorphous SiO<sub>2</sub>

Kajihara, Koichi; Miura, Taisuke; Kamioka, Hayato; Hirano, Masahiro; Skuja, Linards; Hosono, Hideo

doi:10.1143/apex.2.056502

Cited by 16 publications

(59 citation statements)

References 14 publications

(23 reference statements)

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“…Purely electronic band (PEB) located at ~7855 cm − 1 and a vibrational sideband (VSB), which is separated from PEB by the energy of the O-O stretching mode, were identified [19]. The peak position of VSB was almost identical to the position expected for interstitial 18 O 2 , indicating that the fraction of interstitial 18 O 2 (f 88 ) is much larger than that of interstitial 16 [20]. The peak decomposition shown in the inset yielded f 66 ≃ 0.05, f 68 ≃ 0.11, and f 88 ≃ 0.84, confirming that the fraction of 18 O atoms in interstitial O 2 (f * ≡ f 88 + f 86 /2) was as large as 90% (~0.89).…”

Section: Methodsmentioning

confidence: 77%

“…This tube was thermally annealed for 1500 h at 500°C to incorporate 18 O-labeled O 2 into the specimens. Interstitial O 2 in a-SiO 2 was measured by infrared photoluminescence (PL) [19,20]. A continuouswave AlGaAs laser diode operated at 765 nm (~1.5 W at sample position) was used as a PL excitation source.…”

Section: Methodsmentioning

confidence: 99%

“…The peak decomposition shown in the inset yielded f 66 ≃ 0.05, f 68 ≃ 0.11, and f 88 ≃ 0.84, confirming that the fraction of 18 O atoms in interstitial O 2 (f * ≡ f 88 + f 86 /2) was as large as 90% (~0.89). The thickness average of total interstitial O 2 concentration (C a T ) evaluated from the PEB intensity [20] was~3.8 × 10 17 cm − 3 .…”

Section: Methodsmentioning

confidence: 99%

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Oxygen-excess amorphous SiO2 with 18O-labeled interstitial oxygen molecules

Kajihara

Hirano

Skuja

et al. 2011

Journal of Non-Crystalline Solids

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Section: Methodsmentioning

confidence: 77%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

Oxygen-excess amorphous SiO2 with 18O-labeled interstitial oxygen molecules

Kajihara

Hirano

Skuja

et al. 2011

Journal of Non-Crystalline Solids

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“…18,22 However, a correction due to changing fractions of interstitial 16 18 O 2 (τ 66 < τ 68 < τ 88 ), and τ is proportional to the PL quantum yield of the PEB. 23 Thus, the variation of the "effective" PL quantum yield with the fractions of 18 O-labeled interstitial O 2 was accounted for by multiplying the observed PEB intensity by a factor f 66 τ 66 /(f 66 τ 66 + f 68 τ 68 + f 88 τ 88 ). f 66 , f 68 , and f 88 were evaluated by simple peak decomposition of the VSB spectrum using three pseudo-Voigt peak functions with peak parameters that were predetermined, as described in Refs.…”

Section: A Sample Preparation and Measurementsmentioning

confidence: 99%

Exchange between interstitial oxygen molecules and network oxygen atoms in amorphousSiO2studied byO18
Kajihara
¹
,
Miura
²
,
Kamioka
³

et al. 2011
Phys. Rev. B
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Amorphous SiO 2 (a-SiO 2) thermally annealed in an oxygen atmosphere incorporates oxygen molecules (O 2) in interstitial voids. When the thermal annealing is performed in 18 O 2 gas, interstitial 18 O 2 as well as interstitial 16 O 18 O and 16 O 2 are formed due to the oxygen exchange with the a-SiO 2 network. The a 1 g (v = 0) → X 3 − g (v = 1) infrared photoluminescence band of interstitial O 2 was utilized to quantitatively analyze the oxygen exchange, taking into account the influences of common network modifiers in synthetic a-SiO 2 (SiOH, SiF, and SiCl groups). The presence of network modifiers does not significantly change the average rate of 18 O transfer from interstitial O 2 to the a-SiO 2 network and its activation energy, suggesting that the network modifiers themselves do not serve as preferential oxygen exchange sites. When the concentration of SiOH groups is low, the oxygen exchange rate is distributed, indicating that only a small part of the network oxygen atoms participates in the oxygen exchange. However, the distribution of the oxygen exchange rate is distinctly narrow in the sample with high SiOH concentration. It is attributed to the redistribution of the network 18 O atoms and the modification of the a-SiO 2 network topology caused by reactions with mobile interstitial water molecules, which are transiently formed by dehydroxylation of paired SiOH groups. The activation energy for the average oxygen exchange rate is larger than that of the permeation of interstitial O 2 in a-SiO 2. Furthermore, the average exchange-free diffusion length of interstitial O 2 below 900 • C (1 μm) is far larger than the scale of the interstitial voids in a-SiO 2 (1 nm). These observations confirm that the oxygen exchange is not necessarily involved in the permeation of interstitial O 2 .

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“…This process adds to the already observed radiative and non radiative decay processes in bulk silica materials. The latter, in particular, has been associated to coupling of O 2 with high energy vibrational modes of the silica matrix or of impurity defects that cannot be activated up to room temperature due to their high energy [12,13]. By contrast, the additional thermally activated decay should be associated to low activation energy processes due to degrees of freedom of oxygen molecule and interaction with neighbouring matrix.…”

Section: Introductionmentioning

confidence: 99%

Photoluminescence and diffusion properties of O₂ molecules in amorphous SiO₂ nanoparticles

Agnello

Cannas

Iovino

et al. 2013

Phys. Status Solidi C

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An experimental study by Raman and Photoluminescence (PL) spectroscopies on the emission and diffusion properties of O2 molecules in amorphous SiO2 nanoparticles of commercial origin with diameters from 14 to 40 nm is reported. Stationary and time resolved PL measurements have been carried out to characterize the Near Infrared (NIR) emission at 1272 nm of O2. Emission features similar to those of bulk silica systems with a sharp PL band and excitation channels in the NIR, at 1070 nm, and in the visible, at 765 and 690 nm are found, with peculiarities arising from embedding O2 in nanostructures. The study of the NIR PL lifetime as a function of temperature down to 10 K enabled to reveal the presence of non radiative processes competitive to the radiative channel and to the non‐radiative one already highlighted and related to high energy vibrational modes of matrix or of impurity sites. By detecting the O2 content of nanoparticles, the dynamics of diffusion in the low temperature range from 98°C up to 177°C has been characterized. The applicability of Fick's theory has been tested, determining the diffusion coefficients and evidencing some peculiarities detectable in the nanosystem. (© 2013 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)

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Isotope Effect on the Infrared Photoluminescence Decay of Interstitial Oxygen Molecules in Amorphous SiO₂

Cited by 16 publications

References 14 publications

Oxygen-excess amorphous SiO2 with 18O-labeled interstitial oxygen molecules

Oxygen-excess amorphous SiO2 with 18O-labeled interstitial oxygen molecules

Exchange between interstitial oxygen molecules and network oxygen atoms in amorphousSiO2studied byO18
Kajihara
¹
,
Miura
²
,
Kamioka
³

et al. 2011
Phys. Rev. B
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Photoluminescence and diffusion properties of O₂ molecules in amorphous SiO₂ nanoparticles

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Isotope Effect on the Infrared Photoluminescence Decay of Interstitial Oxygen Molecules in Amorphous SiO2

Cited by 16 publications

References 14 publications

Oxygen-excess amorphous SiO2 with 18O-labeled interstitial oxygen molecules

Oxygen-excess amorphous SiO2 with 18O-labeled interstitial oxygen molecules

Exchange between interstitial oxygen molecules and network oxygen atoms in amorphousSiO2studied byO18Kajihara1, Miura2, Kamioka3 et al. 2011Phys. Rev. BSelf Cite90110View full textAdd to dashboardCite

Photoluminescence and diffusion properties of O2 molecules in amorphous SiO2 nanoparticles

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Isotope Effect on the Infrared Photoluminescence Decay of Interstitial Oxygen Molecules in Amorphous SiO₂

Exchange between interstitial oxygen molecules and network oxygen atoms in amorphousSiO2studied byO18
Kajihara
¹
,
Miura
²
,
Kamioka
³

et al. 2011
Phys. Rev. B
Self Cite
9
0
11
0
View full text Add to dashboard Cite

Photoluminescence and diffusion properties of O₂ molecules in amorphous SiO₂ nanoparticles