7 Solubility of oxidized and reduced carbon as a function of Na/Si ra...Figure 8 Solubility of nitrogen in quenched Na2Si4O9 melt as a function of p...Figure 9 Sulfur solubility in Na2O–SiO2 melts as a function of redox conditi...Figure 10 Solubility of nonreactive gases in tholeiite basalt melts at ambie...48 Chapter 5.6Figure 1 Ellingham diagram as modified by Richardson and Jeffes [4]: Δr G° (...Figure 2 Ellingham diagram (after [6]) for several oxides in the float‐glass...Figure 3 Kinetic modes for the oxidation of a Fe2+‐rich aluminosilicate glas...Figure 4 Schematic illustration of small polaron dynamics in silicate glassm...Figure 5 Open‐system redox dynamics in the NCS‐on‐Sn float‐glass process [6]...Figure 6 Thermodynamic analysis associated with open‐system reduction and cl...
49 Chapter 5.7Figure 1 Optical absorption spectrum (in the UV region) of Pb2+ probe ion di...Figure 2 Plot of oxide(‐II) polarizability, αoxide(‐II), versus o...Figure 3 Plot of oxide(‐II) electronegativity, xO, in binary oxides MaOb, ag...Figure 4 Schematic bonding chart for binary oxides (abbreviated for clarity)...
50 Chapter 5.8Figure 1 Three kinds of glass electrode design for pH and pM measurements. (...Figure 2 Extent of linearity of the E–pH relationship of a 22 mol % Na2O sil...Figure 3 Structural role of elements as determined from electrode properties...Figure 4 Typical profiles of ion concentrations in the surface layers of gla...
51 Chapter 5.9Figure 1 Experimental set up for measurements of oxygen activities in a glas...Figure 2 Experimental set up for voltammetric measurements in glass melts.Figure 3 Effects of temperature on peak potentials in voltammograms recorded...Figure 4 Effects of (MgO, SiO2) substitution on peak potentials in voltammog...Figure 5 Voltammetric peak potentials as a function of the MgO concentration...Figure 6 Voltammetric peak potentials of the Cu+/Cu2+ peak as a function of ...Figure 7 Effect of temperature on the electrochemical series for a glass wit...Figure 8 Arrhenius plot of the diffusion coefficients of various polyvalent ...Figure 9 Arrhenius plot for the mean diffusion coefficients of Cu+/Cu2+ for ...Figure 10 Voltammogram recorded for a green glass melt (curve 1) and a melt ...Figure 11 Impedance spectra in a melt with the basic composition 16 Na2O·15 ...Figure 12 Equivalent circuit used to simulate the obtained impedance spectra...Figure 13 Dependence of the Warburg parameter on the superimposed d.c. poten...
52 Chapter 5.10Figure 1 Scheme of a liquid sessile drop in equilibrium with a solid substra...Figure 2 Successive temperature–time steps of the “transferred drop” variant...Figure 3 Scale of formal potential (Ef) at 1050 °C of the main redox couples...Figure 4 Chromium solubility (at %) and residual sulfur content (wt %) in a ...Figure 5 Pathway for the formation of layers at the metal/molten glass inter...Figure 6 Sketch of a working electrode for corrosion characterization of met...Figure 7 Effects of tellurium reduction on platinum stability in argon atmos...Figure 8 Passivation plateau of chromium seen in anode polarization measurem...Figure 9 Anodic polarization curves of Co‐based alloy in borosilicate glass ...
53 Chapter 5.11Figure 1 Cation exchange described by reaction (1) at the surface of a soda‐...Figure 2 Diffusion‐controlled nature of the alteration reaction (1) demonstr...Figure 3 The very strong sensitivity to pH of the solubility of silica glass...Figure 4 Effect of solution renewal on the dissolution kinetics of a soda‐li...Figure 5 Average number of layers of molecular water on the surface of vario...Figure 6 Effect of rinsing on the inner surface of a soda–lime bottle after ...Figure 7 Optical micrography of large CaCO3 crystal present on the inner sid...
54 Chapter 5.12Figure 1 Cross‐sectional diagrams of early models of an altered glass layer....Figure 2 The distinct chemistry and structure of the three layers of the lea...Figure 3 The interdiffusion zone, gel, and surficial crystalline phases of t...Figure 4 Chemical profiles of pristine glass–hydrated glass interface obtain...Figure 5 Hybrid leached‐layer preferential dissolution model [6] illustrated...Figure 6 Glass corrosion by CIDR. (a) Initial stage: congruent glass dissolu...Figure 7 Corrosion of SON68 borosilicate glass altered at 50 °C in water for...Figure 8 Chemical evolution of SON68 borosilicate glass after one month of c...Figure 9 Complex chemical patterns and prevalent μm‐sized porosity of silica...Figure 10 Aqueous elemental release curves as a function of time measured du...
55 Section VIFigure 1 Coloration in a thirteenth‐century stained glass of Chartres cathed...
56 Chapter 6.1Figure 1 Reflection and refraction of a light hitting a glass surface from t...Figure 2 Light reflected by a glass surface.Figure 3 Light passing through interfaces where the index of refraction is c...Figure 4 Index of refraction of SiO2 glass (Corning code 7940) from the ultr...Figure 5 Abbe diagram for inorganic glasses and organic polymers. WG, soda‐l...Figure 6 External refraction and total internal reflection in glass. (a) Ref...Figure 7 Relationship between absorption peak and refractive index.Figure 8 Absorption spectrum of window glass.Figure 9 Effect of composition on room‐temperature refractive indices at 589...Figure 10 Refraction of a light beam coming from the left and traveling para...
57 Chapter 6.2Figure 1 French stained glass from the thirteenth century (cf. Figure VI). (...Figure 2 Glass coloration as examined from the standpoints of absorption and...Figure 3 Successive splittings of d‐orbitals of transition elements in diffe...Figure 4 Influence of the electronic configuration on the optical absorption...Figure 5 Optical spectra and structural models explaining the color of purpl...Figure 6 Effect of nickel coordination on the absorbance spectra (derived fr...Figure 7 Molar extinction coefficients of Cr3+ in K‐, Na‐, and Li‐trisilicat...Figure 8 Influence of the nature of the alkali cation on the intensity but n...Figure 9 Variation of Cr3+ crystal‐field splitting, represented as the cryst...Figure 10 Linear absorbance spectra of Cr3+ and (CrO4)2− in soda‐lime‐...Figure 11 Green Cr‐containing glasses turning yellow at ca. 500 °C, a direct...Figure 12 Modification of the optical absorption spectrum of Cr3+ in a potas...Figure 13 Coloration arising from charge transfer processes. (a) Dark color ...Figure 14 Transmittance curves for the crown glass used for Photogray Extra®...
58 Chapter 6.3Figure 1 Photoluminescent glasses involving, from left to right, doping with...Figure 2 Electronic transitions in sodium. (a) Electronic configuration of a...Figure 3 Elastic and inelastic scattering of red (top) and green (bottom) la...Figure 4 Spectral characteristics of photoluminescence from Eu3+‐doped glass...Figure 5 Different schemes of photoluminescence: (a) downconversion in a thr...Figure 6 Sensitization through co‐doping: an efficient absorption in a certa...Figure 7 Excited state configuration of various trivalent rare earth ions. T...Figure 8 Photoluminescence from Cr3+ in a phosphate glass matrix (simplified...Figure 9 Simplified representation of the electronic states in some opticall...
59 Chapter 6.4Figure 1 Colladon's experiment with flowing water as a waveguide [1].Figure 2 Dispersion curves for silica (top) and for selected MOF/PCF fibers ...Figure 3 “V‐curves” of theoretical attenuation as a function of wavelength f...Figure 4 (a) Total internal reflection, single/multi/and GI fiber designs, (...Figure 5 Sketch of the chemical vapor deposition process (a) modified chemic...Figure 6 Sketch of the fiber‐draw process.
60 Chapter 6.5Figure 1 Influence of atomic weight and bond strength on the infrared transp...Figure 2 Shift to lower wavelengths and intensity increase with temperature ...Figure 3 Structure of ZrF4 glass reticulated by ZrF7 or ZrF8 polyhedral unit...Figure 4 Comparison between the infrared transparencies of silica and fluori...Figure 5 Production of a single‐mode preform (C) from two Se–Te vitreous all...Figure 6 Optical configuration of a single‐mode fluoride fiber used for lase...Figure 7 Laser emission of rare earth‐doped fibers. (a) Comparison between t...Figure 8 Structure of chalcogenide glasses as determined by solid‐state NMR....Figure 9 High‐precision molding of chalcogenide glasses as lenses ready to b...Figure 10 Ceramization of chalcogenide glass disks in which the controlled s...Figure 11 The
