The variation of the stress optical coefficient with glass composition

Nissle, Tod Renard, 1948-

January 1973

No description available.

Glass -- Optical properties.

Optical glass.

Optical nonlinearities in semiconductor doped glass channel waveguides.

Banyai, William Charles.

January 1988

The nonlinear optical properties of a semiconductor-doped glass (SDG) channel waveguide were measured on a picosecond time-scale; namely, fluence-dependent changes in the absorption and the refractive index as well as the relaxation time of the nonlinearity. Slower, thermally-induced changes in the refractive index were also observed. The saturation of the changes in the absorption and the refractive index with increasing optical fluence is explained using a plasma model with bandfilling as the dominant mechanism. The fast relaxation time of the excited electron-hole plasma (20 ps) is explained using a surface-state recombination model. A figure of merit for a nonlinear directional coupler fabricated in a material with a saturable nonlinear refractive index is presented. The measured nonlinear change in the refractive index of the SDG saturates below the value required to effect fluence-dependent switching in a nonlinear directional coupler. Experiments with a channel-waveguide directional coupler support this prediction. However, absorption switching due to differential saturation of the absorption in the two arms of the directional coupler was observed.

Semiconductor doping.

Optical glass -- Optical properties.

Optical properties of distributed feedback waveguide lasers based on Sol-gel glass. / 溶凝膠分佈反饋波導激光器之光學性質的研究 / CUHK electronic theses & dissertations collection / Optical properties of distributed feedback waveguide lasers based on Sol-gel glass. / Rong ning jiao fen bu fan kui bo dao ji guang qi zhi guang xue xing zhi de yan jiu

January 2004

Shi Lei = 溶凝膠分佈反饋波導激光器之光學性質的研究 / 石蕾. / "September 2004." / Thesis (Ph.D.)--Chinese University of Hong Kong, 2004. / Includes bibliographical references (p. 150-171) / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Mode of access: World Wide Web. / Abstracts in English and Chinese. / Shi Lei = Rong ning jiao fen bu fan kui bo dao ji guang qi zhi guang xue xing zhi de yan jiu / Shi Lei.

Lasers

Optical wave guides

Colloids--Optical properties

Glass--Optical properties

Incorporação de nanopartículas de prata em de vidros teluritos dopados com Pr3+ / Silver nanoparticles incorporation in Pr3+ doped tellurite glasses

Taniguchi, Maiara Mitiko

19 February 2018

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / No intuito de melhorar a eficiência de dispositivos ópticos, pesquisadores têm investigado os efeitos da incorporação de nanopartículas metálicas em materiais contendo terras-raras. Neste trabalho, foram estudados os efeitos da variação de AgNO3 em vidros teluritos (72,5TeO2-23WO3-3Na2CO3-1,5Nb2O5 (% em mol)) dopados com 0,1% em mol de Pr3+ produzidos pelo método de fusão seguido de tratamento térmico. As amostas foram caracterizadas por Difratometria de Raios X (DRX), Espectroscopia de Infravermelho com Transformada de Fourier (FTIR), Calorimetria Exploratória Diferencial (DSC), espectroscopia de absorção e luminescência, tempo de vida e índice refração. As curvas de DRX evidenciaram a natureza não-cristalina das amostras enquanto que os espectros de FTIR mostraram que os grupos vibracionais não sofrem alterações após a adição de prata. Por meio das curvas de DSC foi verificado um aumento de aproximadamente 70°C na estabilidade térmica dos vidros TWNN com a adição de prata. A partir dos espectros de absorção na região do visível foi possível verificar a banda de ressonância de plasmon de superfície (SPR) centrada em 500 nm. As medidas de luminescência, por sua vez, mostraram um aumento e quenching nas intensidades das bandas provenientes das transições eletrônicas do Pr3+. Foi observado que a banda entre 480-520 nm apresenta quenching, isso se deve possivelmente pela proximidade da banda SPR. As bandas entre 575-675 nm, por sua vez, tiveram uma melhora na intensidade das luminescências devido à incorporação das AgNPs evidenciando que a adição de AgNO3 proporciona melhorias na intensidade de algumas transições eletrônicas do íon Pr3+. Trabalhos futuros envolvendo medidas complementares serão realizados bem como o uso de outros íons terras-raras na matriz TWNN. / In order to improve the efficiency of optical devices, researchers have investigated the effects of the incorporation of metallic nanoparticles into materials containing rare earth. In this work, the effects of AgNO3 variation on doped telurite glass with 0.1 mol% of Pr3+ produced by the melting-quenching method were studied. The samples were characterized by X-ray diffraction (XRD), Fourier Transform Infrared Spectroscopy (FTIR), Differential scanning calorimetry (DSC), absorption and luminescence spectroscopy, lifetime and index refraction. The XRD curves demonstrated the non-crystalline nature of the samples whereas the FTIR spectra showed that the vibrational groups did not change after silver addition. By means of the DSC curves an increase of approximately 70 °C in the thermal stability of the TWNN glasses with the addition of silver was verified. From the absorption spectra in the visible region it was possible to verify the surface plasmon resonance band (SPR) centered at 500 nm. The luminescence measurements, in the other hand, showed an increase and quenching in the intensities of the bands coming from the electronic transitions of Pr3+. It was observed that the band between 480-520 nm presents quenching, this is possibly due to the proximity of the SPR band. The bands between 575-675 nm, in turn, had an improvement in the intensity of the luminescences due to the incorporation of AgNPs evidencing that the addition of AgNO3 provides improvements in the intensity of some electronic transitions of the Pr3+ ion. Future works involving complementary measures will be performed as well as the use of other rare earth ions in the TWNN matrix.

CNPQ::ENGENHARIAS::ENGENHARIA QUIMICA

Vidro - Propriedades ópticas

Vidro - Propriedades térmicas

Análise térmica

Espectroscopia de infravermelho

Glass - Optical properties

Glass - Thermal properties

Thermal analysis

Infrared spectroscopy

Engenharia Química

Investigations Into The Structural, Dielectric And Optical Properties Of Glasses Containing Electro-Optic Components And Single Crystals Of Molecular Electro-Optic Materials

Shankar, M V

10 1900

No description available.

Electrooptics - Materials

Nonlinear Optics

Glass - Electric Properties

Glass - Optical properties

Nonlinear Optical Materials (NLO)

Electro-optic Materials

Electro-optic Ceramics

NLO Crystals

Materials Science

Investigations into the Structural and Physical Properties of Li2O-M2O-2B2O3 (M=Li, Na & K), BaO-TiO2-B2O3 and 2Bi2O3-B2O3 Glass Systems

Paramesh, Gadige

January 2013

Borate glasses and glass-nano/microcrystal composite fabrication and investigations into their physical properties, have been interesting from their multifunctionalities view point. Certain borate structural units possess high hyperpolarizabilities and give rise to high nonlinear optical effects. High refractive index materials are important for photonic applications. Heavy metal oxide (Bi2O3) containing compounds have high refractive indices. Glasses embedded with wide band-gap semiconducting oxide crystals such as TiO2 received much attention due to their easy processing, stability and promising physical properties. Though TiO2 is used as nucleating agent to fabricate glass-ceramics of various phases, crystallization of TiO2 in glass matrices is difficult and the data are scarce in the literature. Therefore it was worth attempting to find glass compositions in which one can obtain TiO2 crystallization in large volume fractions. Towards this TiO2 crystallization was accomplished in BaO-TiO2-B2O3 glass matrix over wide composition ranges by tuning the concentration of BaO-TiO2 content in B2O3 network. The physical properties of these glasses of various compositions and glass-nanocrystal composites of TiO2 phase (anatase) were investigated. Interestingly BaO-TiO2-B2O3 glasses found to be hydrophobic in nature. The results obtained in the present research work are classified into five chapters apart from the Introduction, Materials and Methods chapters. Chapter 1 constitutes preface to oxide glasses, principles of glass formation and structural criteria followed by crystallization kinetics. In addition, principles of dielectric, optical and mechanical phenomena in glasses are discussed, since the present thesis focuses on the aforesaid physical properties. This chapter concludes with scope of the present thesis. Chapter 2 includes the detailed description concerning the fabrication techniques of materials under study and various characterization methods that have been employed at various stages of the present research work. The principles and experimental tools adopted for the structural and microstructural studies of materials were illustrated. Measurement techniques and experimental setup used to study physical parameters such as dielectric, optical, mechanical etc. were elaborated. Chapter 3 comprises structural, dielectric, electrical transport characteristics and optical studies of mixed alkali borate glasses in the 0.5Li2O-0.5M2O-2B2O3 (M=Li, Na and K) system. Transparent glasses in the Li2O-2B2O3 (LBO), 0.5Li2O-0.5Na2O-2B2O3 (LNBO) and 0.5Li2O-0.5K2O-2B2O3 (LKBO) were fabricated via the conventional melt quenching technique. Amorphous and glassy nature of the samples was confirmed via the X-ray powder diffraction and the differential scanning calorimetry, respectively. LKBO glass was found to have high thermal stability than that of LBO and LNBO. The frequency and temperature dependent characteristics of the dielectric relaxation and the electrical conductivity were investigated in the 100 Hz - 10 MHz frequency range. The relaxation and conductivity were rationalized using impedance and modulus formalism. Imaginary part of the electric modulus spectra was modelled using an approximate solution of Kohlrausch-Williams-Watts relation. The stretching exponent, β, was found to be temperature independent for LNBO glasses. Activation energies for conduction and relaxation process were calculated using the Arrhenius relation. The activation energy was found to be higher (1.25eV) for LKBO glasses than that of the other glass systems under study. This is attributed to the mixed cation effect. It has wide optical transmission window and optical band gap. Urbach energies were calculated for all these glasses. LBO, LNBO and LKBO glass compositions were found to crystallize in Li2B4O7, LiNaB4O7 and LiKB4O7 phases respectively upon heat treatment at appropriate temperatures. Transparent glass-micro crystal composites of LiKB4O7 were fabricated from LKBO glasses and found to be SHG active. BaO-TiO2-B2O3 Chapter 4 delineates the evolution of nanocrystalline TiO2 phase (Anatase) in BaO-TiO2-B2O3 (BTBO) glasses. Transparent colourless glasses in the ternary system were fabricated via conventional melt-quenching technique. The glasses with certain molar concentrations of BaO and TiO2 upon heat treatment at appropriate temperatures yielded nanocrystalline phase of TiO2 associated with the crystallite size in the 5-15 nm range. Nanocrystallized glasses exhibited high refractive index (no=2.15) at λ=543nm. These glasses were found to be hydrophobic in nature associated with the contact angle of 90o. These high index glass nanocrystal composites would be of potential interest for optical device applications. Crystallization kinetics of anatase phase in BTBO glasses were studied using non-isothermal Differential Scanning Calorimetry (DSC) at three different heating rates (10, 20 & 30 K/min). Scanning Electron Microscopy (SEM) carried out on heat treated (at 920 K) glasses confirmed bulk nucleation and three-dimensional growth. Johnson-Mehl-Avrami model could not be applied for this system suggesting considerable overlap of the nucleation and growth involving complex transformation process. However, modified Kissinger and Ozawa models were used to calculate the effective activation energy associated with anatase crystallization. The kinetic exponent n was found to be temperature dependent indicating the change in the crystallization mechanism. This is attributed to the high entropy fusion of anatase phase, fast crystallization rate and nano dimension of the anatase phase. Chapter 5 illustrates structural changes that occur in the x(BaO-TiO2)-B2O3 (x=0.25, 0.5, 0.75 &1 mol.) system on increasing the x apart from the details concerning some physical property correlations. Thermal stability and glass forming ability as determined by Differential Thermal Analysis (DTA) were found to increase with increasing BaO-TiO2 (BT) content. However, there was no noticeable change in the glass transition temperature (Tg). This was attributed to the active participation of TiO2 in the network formation especially at higher BT contents via the conversion of the TiO6 structural units into TiO4 units which increased the connectivity and resulted in an increase in crystallization temperature. Dielectric and optical properties at room temperature were studied for all the glasses under investigation. Interestingly, these glasses were found to be hydrophobic. The results obtained were correlated with different structural units present in the glass and their connectivity. These glasses exhibited low loss (tan δ≈0.002), frequency (10 kHz- 10 MHz) and temperature independent (or very weak temperature response) flat-dielectric response. Crossover temperature was encountered between flat response and Jonscher’s universal response. The cross-over temperature and cross-over energy barrier from flat dielectric response to Jonscher’s response was deduced for all the glasses in the present investigation. Electric modulus formalism was invoked to rationalize the relaxation phenomena. The observed dielectric response and conduction process in these glasses were attributed to the local vibration and switching of non-bridging oxygen ions in their potential cage and hopping over distributed energy barriers above the crossover temperature. Chapter 6 depicts the dielectric and mechanical properties of glasses embedded with TiO2 nanocrystals. BaO-TiO2-B2O3 glasses on subjecting to appropriate heat treatment temperature yielded TiO2 nano crystalline anatase phase. NMR studies carried out on the as-quenched glasses facilitated the estimation of fraction of tetrahedral and trigonal borate units. Poisson’s ratio and Young’s modulus were evaluated through theoretical expressions proposed by Makishima and Mackenzie. Nano-indentation and micro-indentation studies were carried out on the as-quenched glasses and glass-nanocrystal composites to examine mechanical characteristics. Estimated and indentation Young’s modulus of glasses were found to be in reasonable agreement. Hardness and Young’s modulus increased with increasing fraction of nano crystallites whereas fracture toughness was found to depend strongly on surface conditions. The results were corroborated by the structural units and particulates present in these glasses. Dielectric constant increased with increasing volume fraction of the nanocrystals which was rationalized via mixture rule. Chapter 7 describes the dielectric properties, electrical conduction and electric relaxation phenomena in 2Bi2O3-B2O3 (BBO) glasses followed by thier linear and nonlinear optical characteristics. Glasses in BBO system were obtained via melt-quenching technique. X-ray diffraction and differential scanning calorimetry were used to study the structural characteristics. Dielectric studies carried out on these glasses revealed near constant loss (NCL) response in the 1 kHz to 1 MHz frequency range at moderately high temperatures (300-450 K) accompanied by relatively low loss (tan δ=0.006, at 1 kHz & 300 K) and high dielectric constant (ε' =37, at 1 kHz & 300 K). The variation in AC conductivity with temperature at different frequencies showed a cross over from NCL response characterized by local ion vibration within the potential well to universal Jonscher’s power law dependence triggered by ion hopping between potential wells or cages. Thermal activation energy for single potential well was found to be 0.48±0.05 eV from cross over points. Ionic conduction and relaxation processes were rationalized by modulus formalism. The promising dielectric properties (relatively high ε' and low tan δ) of the BBO glasses were attributed to high density (93 % of its crystalline counterpart), high polarizability and low mobility associated with heavy metal cations, Bi3+. Optical band gap obtained for BBO glasses was found to be 2.6 eV. The refractive index measured for these glasses was 2.25±0.05 at λ=543 nm. Nonlinear refraction and absorption studies were carried out on BBO glasses using z-scan technique at λ=532 nm of 10 ns pulse width. The nonlinear refractive index obtained was n2=12.1x10-14 cm2/W and two-photon absorption coefficient was β=15.2 cm/GW. The n2 and β values of the BBO glasses were higher than that reported for high index bismuth based oxide glass systems in the literature. These were attributed to the high density, high linear refractive index, low band gap and two-photon absorption associated with these glasses. The electronic origin of large nonlinearities was discussed based on bond-orbital theory. Thesis ends with summary and conclusions followed by prospective views, though each chapter comprises conclusions associated with complete list of references. Patent, publications and conference proceedings that are listed below are largely based on the studies conducted as a part of the research work reported in the present thesis.

Glass

Glass - Structural Properties

Glass - Mechanical Properties

Glass - Dielectric Properties

Glass - Optical Properties

Glass - Nanocrystallization

Glass Nanocrystal Composites

Glass-Ceramics

Alkali Borate Glasses

Transparent Glasses

Glass - Fabrication

Glass Nanocrystal Composites

BaO–TiO2–B2O3 Glasses

Nanocrystal Glass Composites

ZnO–Bi2O3–B2O3 Glasses

Materials Science