Influence of lattice modifier on the nonlinear refractive index of tellurite glass

Santos, Felipe A.; Figueiredo, M. S.; Barbano, E. C.; Misoguti, Lino; Lima, S.M.; Andrade, L.H.C.; Yukimitu, K.; Moraes, João Carlos Silos

doi:10.1016/j.ceramint.2017.08.054

Cited by 31 publications

(6 citation statements)

References 32 publications

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“…The above bands have been contributed by three different types of stretching vibrations, ie, the stretching modes of Te‐O‐Te or O‐Te‐O linkage, stretching modes of Te‐O bond in TeO 4 trigonal bipyramid (tbp), and bending modes of Te‐O bond in TeO 3+1 or TeO 3 trigonal pyramid (tp) units, respectively. These characteristic peaks are similar to those reported previously for tellurite glasses 39–41 . Despite the shape of the bands is not changed by bits of GeO 2 and B 2 O 3 addition, slight shifts of band positions happen in TZNGB glass.…”

Section: Resultssupporting

confidence: 89%

“…These characteristic peaks are similar to those reported previously for tellurite glasses. [39][40][41] Despite the shape of the bands is not changed by bits of GeO 2 and B 2 O 3 addition, slight shifts of band positions happen in TZNGB glass. The blue shift of Te-O-Te stretching vibration is due to the deformation of Te-O-Te bond caused by the introduction of GeO 2 .…”

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confidence: 99%

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The fabrication of nanodiamond doped tellurite germanate glass with robust structure and its luminescence

Gan

et al. 2020

J Am Ceram Soc

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Fluorescence of negative‐charged nitrogen‐vacancy centers in nanodiamond allows applications in quantum metrology, nanoscale sensor, and bioimaging, of utmost relevance to domains from nanotechnologies to biosensing. However, the low color center content and collection efficiency of photons are crucial issues. Although, several studies about coupling nanodiamond into optical waveguides have already been proposed, the search for the most appropriate substance and simplest, most effective method are of keys. In this study, we present a novel nontraditional way to incorporate nanodiamond with increased negative‐charged nitrogen‐vacancy content to 75.48% into tellurite germanate glass. The hybrid glass is stable in structure with predominant TeO4 trigonal bipyramid. Moreover, the fluorescence intensity is enhanced in composite. Such robust nanodiamond in tellurite germanate glass optical system has the potential to be used for nanoparticle sensing and quantum metrology.

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Section: Resultssupporting

confidence: 89%

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confidence: 99%

The fabrication of nanodiamond doped tellurite germanate glass with robust structure and its luminescence

Gan

et al. 2020

J Am Ceram Soc

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“…[27,28] Tellurite glass not only has good forming ability but also has a large refractive index in the visible to nearinfrared band. [29,30] As is well known, a large refractive index is conducive to the occurrence of the elastic-optic effect. [31] Therefore, we speculated that tellurate glass may combine the advantages of the excellent AO properties of TeO 2 crystal and the easy large-size preparation of glass, and will efficiently promote the development of the AO field.…”

Section: Introductionmentioning

confidence: 99%

High‐Quality Acousto‐Optic Modulators with High Diffraction Efficiency, Polarization Extinction Ratio, and Small Insertion Loss Based on a Novel BaO–TeO₂–WO₃ Glass

Guo,

Hu,

Chen

et al. 2023

Advanced Materials

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The Q‐switched material and device have attracted extensive attention due to their irreplaceable role in pulsed lasers. In this paper, BaO‐TeO2‐WO3 glass (BTW glass) with sound velocity and sound attenuation coefficient of 3422 m −1s and 0.653 dB/cm is successfully selected and fabricated as acousto‐optic material. Both free‐spaced and fiber‐coupled acousto‐optic modulation devices based on BTW glass are designed and fabricated. The primary parameters such as diffraction efficiency, polarization extinction ratio, and insertion loss are comparable to or even surpassed that of commercial devices. A 1064 nm pulsed laser is successfully realized with a BTW glass free‐spaced acousto‐optic modulator. The maximum optical conversion efficiency, the narrowest pulse width, and the maximum single pulse energy of the 1064 nm pulsed laser are 32%, 54 ns, and 242.6 μJ, respectively. Both the device and laser performance indicate that the BTW glass is a remarkable acousto‐optic material.This article is protected by copyright. All rights reserved

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“…(8,9) The addition of transition metal oxides in tellurite glasses modifies the structure by forming new ionic bonds and creates nonbridging oxygens that affect the electrical conductivity, thermal stability and optical properties of glasses. (10)(11)(12)(13) The addition of metal ions elongates one oxygen-tellurium linkage in TeO 4 and forms TeO 3+1 and TeO 3 structural units. (14)(15)(16) It is important to determine the structural properties of tellurite glasses; in particular the Te 4+ and the modifier ion co-ordination environment, bond lengths, nearest neighbour distances and the bond angle distributions to model the mechanical, optical, thermal, electrical and magnetic properties of glasses.…”

Section: Introductionmentioning

confidence: 99%

“…Figure13. FTIR absorbance spectra of copper tellurite and borotellurite glasses[Colour available online] …”

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confidence: 99%

Structure of copper tellurite and borotellurite glasses by neutron diffraction, Raman, 11B MAS-NMR and FTIR spectroscopy

Kaur

Khanna

Krishna

et al. 2020

Phys. Chem. Glasses: Eur. J. Glass Sci. Technol. B

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The structure of copper tellurite and borotellurite glasses is studied by x-ray and neutron diffraction, reverse Monte Carlo (RMC) simulations, FTIR, Raman and 11B MAS-NMR spectroscopy. Copper tellurite sample with 15 mol% CuO forms precipitates of tetragonal TeO2 within the glass matrix on melt quenching. The glass forming ability of the xCuO–(100−x)TeO2 system enhances with increase in CuO concentration from 15 to 20 mol% and also with the addition of B2O3. RMC simulations on the neutron diffraction data found that the Cu–O and Te–O bond lengths are approximately at equal distances in the range: 1·96 to 1·98±0·02 Å, while the nearest O–O distance is at 2·71±0·02 Å. Neutron and Raman results on the Te–O speciation are in agreement and confirmed that the Te–O coordination decreases with an increase in CuO and B2O3 molar concentrations in the tellurite and borotellurite glasses, respectively. RMC studies found that Cu2+ has tetrahedral coordination with oxygen, as predicted by Jahn–Teller distortion and that Cu–O and Te–O structural units have very similar size and geometry. The copper tellurite glass-ceramic sample with 15 mol% CuO was heat treated and it formed crystalline precipitates of TeO2 and CuTe2O5 upon devitrification; the average Te–O coordination was significantly smaller in the glass as compared to that in the crystalline sample.

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Influence of lattice modifier on the nonlinear refractive index of tellurite glass

Cited by 31 publications

References 32 publications

The fabrication of nanodiamond doped tellurite germanate glass with robust structure and its luminescence

The fabrication of nanodiamond doped tellurite germanate glass with robust structure and its luminescence

High‐Quality Acousto‐Optic Modulators with High Diffraction Efficiency, Polarization Extinction Ratio, and Small Insertion Loss Based on a Novel BaO–TeO₂–WO₃ Glass

Structure of copper tellurite and borotellurite glasses by neutron diffraction, Raman, 11B MAS-NMR and FTIR spectroscopy

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Influence of lattice modifier on the nonlinear refractive index of tellurite glass

Cited by 31 publications

References 32 publications

The fabrication of nanodiamond doped tellurite germanate glass with robust structure and its luminescence

The fabrication of nanodiamond doped tellurite germanate glass with robust structure and its luminescence

High‐Quality Acousto‐Optic Modulators with High Diffraction Efficiency, Polarization Extinction Ratio, and Small Insertion Loss Based on a Novel BaO–TeO2–WO3 Glass

Structure of copper tellurite and borotellurite glasses by neutron diffraction, Raman, 11B MAS-NMR and FTIR spectroscopy

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High‐Quality Acousto‐Optic Modulators with High Diffraction Efficiency, Polarization Extinction Ratio, and Small Insertion Loss Based on a Novel BaO–TeO₂–WO₃ Glass