Effects of fluorine dimer excimer laser radiation on the optical transmission and defect formation of various types of synthetic SiO2 glasses

Hosono, Hideo; Mizuguchi, Masafumi; Kawazoe, Hiroshi; Ogawa, Tohru

doi:10.1063/1.124004

Cited by 86 publications

(42 citation statements)

References 17 publications

(10 reference statements)

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“…The suggested mechanism of this phenomenon is the stabilization of radiation-created oxygen interstitials by transforming them to silanol bonds. A dramatic improvement of VUV transparency and excimer laser toughness takes place [65] in silica glass doped by fluorine (≈0.1-1 wt%). Fluorine is incorporated in silica mainly [66] in the form of SiF groups, which help to relax the silica network by building into the strained sites (Fig.…”

Section: Strained Bonds and Role Of Hydrogen And Fluorine Dopantsmentioning

confidence: 99%

Defects in oxide glasses

Skuja

Hirano

Hosono

et al. 2005

phys. stat. sol. (c)

242

168

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Section: Strained Bonds and Role Of Hydrogen And Fluorine Dopantsmentioning

confidence: 99%

Defects in oxide glasses

Skuja

Hirano

Hosono

et al. 2005

phys. stat. sol. (c)

242

168

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“…In 1980s, such F-doping effects had attracted much attention for fiber applications. Then, it was also found that F-doping improves the resistance to vacuum-ultraviolet (UV) light (<200 nm) 21) and gammaray irradiation, 23)25) and silica glass became available as optical materials for vacuum-UV applications, as shown in Fig. 3.…”

Section: Fluorine Doping Of Silica Glass 21 Discovery Of Fluorine Domentioning

confidence: 99%

“…ppm F-doping. 49) Hosono et al 21) examined the radiation toughness of several silica glasses; F-doped silica glass, dry silica glass (the SiOH content <1 ppm), and wet silica glass (the SiOH content ³120 ppm). The concentration of the residual OH bond in the F-doped glass was close to that in the dry silica glass.…”

Section: Mechanism Of F-doping Effectmentioning

confidence: 99%

Doping effects in amorphous oxides

Funabiki

Kamiya

Hosono

2012

J. Ceram. Soc. Japan

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Impurity doping of crystalline Si is one of the most striking techniques in semiconductor technology. A rigid and perfect crystalline lattice is prerequisite for effective doping. However, it has been reported to date that introducing a small amount of impurities drastically improves also the properties of amorphous materials. This paper reviews three pronounced doping effects on optical and electrical properties of amorphous oxides; i.e., (i) F-doping of silica glass to improve the vacuum-ultraviolet optical transmission and radiation toughness, (ii) codoping effects on solubility enhancement of rare earth ions in silica glass melt, and (iii) electron-carrier generation in transparent amorphous oxide semiconductors. It is emphasized that effectiveness of electron doping is determined by the magnitude of electron affinity and stabilization energy of a dopant. Importance of the local structure formed around a dopant ion and the location of conduction band minimum measured from the vacuum level is addressed to understand the doping effects in amorphous oxides.

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“…In general, such point defects result in undesirable degradation of electrical and/or optical properties, but they can also be used to exhibit some specific features or applications. A variety of metastable defects in glasses have been observed under an excimer laser and a femtosecond laser induces a variety of metastable defects [1][2][3]. It is hence likely that some novel optical functions can be elicited if the characteristics and quantities of the defects can be controlled.…”

Section: Introductionmentioning

confidence: 99%

Long-lasting phosphorescence in Mn²⁺:Zn₂GeO₄crystallites precipitated in transparent GeO₂–B₂O₃–ZnO glass-ceramics

Qiu

Igarashi

Makishima

2005

Science and Technology of Advanced Materials

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Mn 2C-doped GeO 2 -B 2 O 3 -ZnO (GBZ) glasses were investigated and developed as long-lasting phosphorescence host materials. Transparent glass-ceramics were obtained after heat-treated at the first crystallization temperature for 20 min. By X-ray diffraction measurement and SEM observation, it is clarified that Zn 2 GeO 4 crystallites with a diameter of about 1 mm precipitate on the sample's surface after heat-treatment. An orange long-lasting phosphorescence from Mn 2C was observed in the 25GeO 2 -25B 2 O 3 -50ZnO glass matrix, however, a stronger long-lasting green phosphorescence was observed in the phase of Zn 2 GeO 4 crystallites. This phenomenon is considered to be due to the different ligand field environment surrounding Mn 2C ions in the glass and the glass-ceramics. A possible mechanism for the long-lasting phosphorescence in the Mn 2C -doped glass was discussed.

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Effects of fluorine dimer excimer laser radiation on the optical transmission and defect formation of various types of synthetic SiO2 glasses

Cited by 86 publications

References 17 publications

Defects in oxide glasses

Defects in oxide glasses

Doping effects in amorphous oxides

Long-lasting phosphorescence in Mn²⁺:Zn₂GeO₄crystallites precipitated in transparent GeO₂–B₂O₃–ZnO glass-ceramics

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Effects of fluorine dimer excimer laser radiation on the optical transmission and defect formation of various types of synthetic SiO2 glasses

Cited by 86 publications

References 17 publications

Defects in oxide glasses

Defects in oxide glasses

Doping effects in amorphous oxides

Long-lasting phosphorescence in Mn2+:Zn2GeO4crystallites precipitated in transparent GeO2–B2O3–ZnO glass-ceramics

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Product

Resources

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Long-lasting phosphorescence in Mn²⁺:Zn₂GeO₄crystallites precipitated in transparent GeO₂–B₂O₃–ZnO glass-ceramics