Glass science in the United States: Current status and future directions

International Journal of Applied Glass Science

Volumn 5, Issue 1, 2014, Pages 2-15

  Mauro, John C ^a   Philip, Charles S ^a   Vaughn, Daniel J ^a   Pambianchi, Michael S ^a  

^a Science and Technology Division   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

ACADEMIC RESEARCH; CHALCOGENIDE GLASS; CURRENT STATUS; GLASS RESEARCH; JOURNAL ARTICLES; PUBLICATION ACTIVITIES; SILICATE GLASS; TRAINING STUDENTS;

GLASS CERAMICS; INDUSTRIAL APPLICATIONS; INDUSTRIAL RESEARCH; SILICATES;

GLASS INDUSTRY;

EID: 84897634406     PISSN: 20411286     EISSN: 20411294     Source Type: Journal    
DOI: 10.1111/ijag.12058     Document Type: Article

References (159)

1. B. Graham and A. Shuldiner, Corning and the Craft of Innovation, 37-38, Oxford University Press, New York, 2001.
2. O. Schott, "Studies on the Toughening of Glass, " Minutes Proc. Inst. Civil Eng. Other Sel. Abst. Papers, LIX 437-440 (1880).
3. K. Bange and M. Weissenberger-Eibl, eds. Making Glass Better: An ICG Roadmap with a 25 Year Glass R&D Horizon. International Commission on Glass, Madrid, Spain, 2010.
4. A. Ellison and I. A. Cornejo, "Glass Substrates for Liquid Crystal Displays, " Int. J. Appl. Glass Sci., 1 [1] 87-103 (2010).
5. B. O. Mysen and P. Richet, Silicate Glasses and Melts, Elsevier, Amsterdam, 2005.
6. L. Cormier, D. Ghaleb, J.-M. Delaye, and G. Calas, "Competition for Charge Compensation in Borosilicate Glasses: Wide-angle X-ray Scattering and Molecular Dynamics Calculations, " Phys. Rev. B., 61 14495-14499 (2000).
7. 17O NMR Study, " J. Non-Cryst. Solids, 351 3508-3520 (2005).
8. J. Wu and J. F. Stebbins, "Quench Rate and Temperature Effects on Boron Coordination in Aluminoborosilicate Melts, " J. Non-Cryst. Solids, 356 2097-2108 (2010).
9. Q. Zheng, M. Potuzak, J. C. Mauro, M. M. Smedskjaer, R. E. Youngman, and Y. Yue, "Composition-Structure-Property Relationships in Boroaluminosilicate Glasses, " J. Non-Cryst. Solids, 358 993-1002 (2012).
10. 2] Ratio on the Structural Role of Sodium, " Phys. Rev. B., 86 054203 (2012).
11. M. M. Smedskjaer, J. C. Mauro, J. Kjeldsen, and Y. Yue, "Microscopic Origins of Compositional Trends in Aluminosilicate Glass Properties, " J. Am. Ceram. Soc., 96[5] 1436-1443 (2013).
12. J. Wu and J. F. Stebbins, "Temperature and Modifier Cation Field Strength Effects on Aluminoborosilicate Glass Network Structure, " J. Non-Cryst. Solids, 362 73-81 (2013).
13. M. M. Smedskjaer, J. C. Mauro, S. Sen, and Y. Yue, "Quantitative Design of Glassy Materials Using Temperature-Dependent Constraint Theory, " Chem. Mater., 22 5358-5365 (2010).
14. M. M. Smedskjaer, J. C. Mauro, and Y. Yue, "Prediction of Glass Hardness Using Temperature-Dependent Constraint Theory, " Phys. Rev. Lett., 105 115503 (2010).
15. M. M. Smedskjaer, J. C. Mauro, R. E. Youngman, C. L. Hogue, M. Potuzak, and Y. Yue, "Topological Principles of Borosilicate Glass Chemistry, " J. Phys. Chem. B, 115 12930-12946 (2011).
16. J. C. Mauro, "Topological Constraint Theory of Glass, " Am. Ceram. Soc. Bull., 90 [4] 31-37 (2011).
17. J. C. Mauro, "Statistics of Modifier Distributions in Mixed Network Glasses, " J. Chem. Phys., 138 12A522 (2013).
18. S. Sakka, "Oxynitride Glasses, " Ann. Rev. Mater. Sci, 16 29-46 (1986).
19. P. Maass, "Towards a Theory for the Mixed Alkali Effect in Glasses, " J. Non-Cryst. Solids, 255 35-46 (1999).
20. G. N. Greaves, "Structural Studies of the Mixed Alkali Effect in Disilicate Glasses, " Solids State Ionics, 105 243-248 (1998).
21. J. Kjeldsen, M. M. Smedskjaer, J. C. Mauro, R. E. Youngman, L. Huang, and Y. Yue, "Mixed Alkaline Earth Effect in Sodium Aluminosilicate Glasses, " J. Non-Cryst. Solids, 369 61-68 (2013).
22. H. Inoue, A. Masuno, and Y. Watanabe, "Modeling of the Structure of Sodium Borosilicate Glasses Using Pair Potentials, " J. Phys. Chem. B, 116 12325-12331 (2012).
23. Y. Xiang, J. Du, M. M. Smedskjaer, and J. C. Mauro, "Structure and Properties of Sodium Aluminosilicate Glasses from Molecular Dynamics Simulations, " J. Chem. Phys., 139 044507 (2013).
24. L. Wondraczek and J. C. Mauro, "Advancing Glasses through Fundamental Research, " J. Euro. Ceram. Soc, 29 1227-1234 (2009).
25. J. C. Mauro, and J. Du, "Achieving Long Time Scale Simulations of Glass-Forming Systems, " Comp. Theo. Chem, 987 122-133 (2012).
26. F. T. Wallenberger and A. Smrcek, "The Liquidus Temperature: Its Critical Role in Glass Manufacturing, " Int. J. Appl. Glass Sci., 1 151-163 (2010).
27. E. B. Ferreira, M. L. Lima, and E. D. Zanotto, "DSC Method for Determining the Liquidus Temperature of Glass-Forming Systems, " J. Am. Ceram. Soc., 93 3757-3763 (2010).
28. J. C. Mauro, Y. Z. Yue, A. J. Ellison, P. K. Gupta, and D. C. Allan, "Viscosity of Glass-Forming Liquids, " Proc. Natl Acad. Sci. USA, 106 19780-19784 (2009).
29. 2 Glass-Forming Systems, " J. Non-Cryst. Solids, 363 39-45 (2013).
30. 2 Glass-Forming Compositions, " Int. J. Appl. Glass Sci., 4 225-230 (2013).
31. P. F. James, "Kinetics of Crystal Nucleation in Silicate Glasses, " J. Non-Cryst. Solids, 73 517-540 (2013).
32. V. M. Fokin, E. D. Zanotto, and J. W. P. Schmelzer, "On the Thermodynamic Driving Force for Interpretation of Nucleation Experiments, " J. Non-Cryst. Solids, 356 2185-2191 (2010).
33. A. A. Cabral, V. M. Fokin, and E. D. Zanotto, "On the Determination of Nucleation Rates in Glasses by Nonisothermal Methods, " J. Am. Ceram. Soc., 93 [9] 2438-2440 (2010).
34. J. W. P. Schmelzer, V. M. Fokin, A. S. Abyzov, E. D. Zanotto, and I. Gutzow, "How Do Crystals Form and Grow in Glass-Forming Liquids: Ostwald's Rule of Stages and Beyond, " Int. J. Appl. Glass Sci., 1 [1] 16-26 (2010).
35. E. D. Zanotto, "Glass Crystallization Research - A 36-Year Retrospective. Part I, Fundamental Studies, " Int. J. Appl. Glass Sci., 4 [2] 105-116 (2013).
36. E. D. Zanotto, "Glass Crystallization Research - A 36-Year Retrospective. Part II, Methods of Study and Glass-Ceramics, " Int. J. Appl. Glass Sci., 4 [2] 117-124 (2013).
37. J. C. Mauro, A. J. Ellison, D. C. Allan, and M. M. Smedskjaer, "Topological Model for the Viscosity of Multicomponent Glass-Forming Liquids, " Int. J. Appl. Glass Sci., 4 [4] 408-413 (2013).
38. I. Avramov, C. Rüssel, N. Kolkovska, and I. Georgiev, "Crystallization Kinetics and Network Rigidity, " J. Phys. Condens. Matter, 20 335203 (2008).
39. P. K. Gupta and J. C. Mauro, "The Laboratory Glass Transition, " J. Chem. Phys., 126 224504 (2007).
40. J. C. Mauro, P. K. Gupta, and R. J. Loucks, "Continuously Broken Ergodicity, " J. Chem. Phys., 126 184511 (2007).
41. J. C. Mauro, R. J. Loucks, and S. Sen, "Heat Capacity, Enthalpy Fluctuations, and Configurational Entropy in Broken Ergodic Systems, " J. Chem. Phys., 133 164503 (2010).
42. A. Y. Sane and A. R. Cooper, "Stress Buildup and Relaxation During Ion Exchange Strengthening of Glass, " J. Am. Ceram. Soc., 70 [2] 86-89 (1987).
43. M. D. Ediger, C. A. Angell, and S. R. Nagel, "Supercooled Liquids and Glasses, " J. Phys. Chem., 100 [31] 13200-13212 (1996).
44. P. G. Debenedetti and F. H. Stillinger, "Supercooled Liquids and the Glass Transition, " Nature, 410 259-267 (2001).
45. J. C. Dyre, "Colloquium: The Glass Transition and Elastic Models of Glass-Forming Liquids, " Rev. Mod. Phys., 78 953-972 (2006).
46. J. C. Mauro, R. J. Loucks, A. K. Varshneya, and P. K. Gupta, "Enthalpy Landscapes and the Glass Transition, " Sci. Model. Simul., 15 241-281 (2008).
47. J. C. Mauro and M. M. Smedskjaer, "Minimalist Landscape Model of Glass Relaxation, " Phys. A, 391 3446-3459 (2012).
48. J. C. Mauro, R. J. Loucks, and P. K. Gupta, "Fictive Temperature and the Glassy State, " J. Am. Ceram. Soc., 92 [1] 75-86 (2009).
49. J. C. Mauro and R. J. Loucks, "Forbidden Glasses and the Failure of Fictive Temperature, " J. Non-Cryst. Solids, 355 676-680 (2009).
50. J. Schmelzer, I. Gutzow, and O. V. Mazurin, Glasses and the Glass Transition, Wiley-VCH Verlag, Weinheim, Germany, 2011.
51. R. J. Araujo and J. C. Mauro, "The Thermodynamic Significance of Order Parameters During Glass Relaxation, " J. Am. Ceram. Soc., 93 [4] 1026-1031 (2010).
52. M. Potuzak, R. C. Welch, and J. C. Mauro, "Topological Origin of Stretched Exponential Relaxation in Glass, " J. Chem. Phys., 135 214502 (2011).
53. J. C. Mauro and A. K. Varshneya, "A Nonequilibrium Statistical Mechanical Model of Structural Relaxation in Glass, " J. Am. Ceram. Soc., 89 [3] 1091-1094 (2006).
54. J. C. Mauro and R. J. Loucks, "Selenium Glass Transition: A Model Based on the Enthalpy Landscape Approach and Nonequilibrium Statistical Mechanics, " Phys. Rev. B., 76 [17] 174202 (2007).
55. J. C. Mauro, D. C. Allan, and M. Potuzak, "Nonequilibrium Viscosity of Glass, " Phys. Rev. B., 80 [9] 094204 (2009).
56. M. A. DeBolt, A. J. Easteal, P. B. Macedo, and C. T. Moynihan, "Analysis of Structural Relaxation in Glass Using Rate Heating Data, " J. Am. Ceram. Soc., 59 [1-2] 16-21 (1976).
57. I. M. Hodge, "Enthalpy Relaxation and Recovery in Amorphous Materials, " J. Non-Cryst. Solids, 169 211-266 (1994).
58. Y.-Z. Yue, "Characteristic Temperatures of Enthalpy Relaxation in Glass, " J. Non-Cryst. Solids, 354 1112-1118 (2008).
59. J. C. Mauro and R. J. Loucks, "Impact of Fragility on Enthalpy Relaxation in Glass, " Phys. Rev. E., 78 021502 (2008).
60. N. O. Birge and S. R. Nagel, "Specific-Heat Spectroscopy of the Glass Transition, " Phys. Rev. Lett., 54 2674-2677 (1985).
61. R. C. Welch, et al., "Dynamics of Glass Relaxation at Room Temperature, " Phys. Rev. Lett., 110 265901 (2013).
62. P. Boolchand, D. G. Georgiev, and B. Goodman, "Discovery of the Intermediate Phase in Chalcogenide Glasses, " J. Optoelectron. Adv. Mater, 3 703-720 (2001).
63. P. Boolchand, G. Lucovsky, J. C. Phillips, and M. F. Thorpe, "Self-Organization and the Physics of Glassy Networks, " Philos. Mag, 85 3823-3838 (2005).
64. 4, " Phys. Rev. B., 79 174201 (2009).
65. A. K. Varshneya, "Chemical Strengthening of Glass: Lessons Learned and Yet to be Learned, " Int. J. Appl. Glass Sci., 1 [2] 131-142 (2010).
66. J. C. Mauro, A. J. Ellison, and L. D. Pye, "Glass: The Nanotechnology Connection, " Int. J. Appl. Glass Sci., 4 [2] 64-75 (2013).
67. L. Wondraczek, et al., "Towards Ultrastrong Glasses, " Adv. Mater., 23 4578-4586 (2011).
68. D. Käfer, et al., "Ultra-Smooth and Ultra-Strong Ion-Exchanged Glass as Substrates for Organic Electronics, " Adv. Func. Mater, 23 [25] 3233-3238 (2013).
69. H. S. Chen, "Ductile-Brittle Transition in Metallic Glasses, " Mat. Sci. Eng, 26 79-82 (1976).
70. D. Jang and J. R. Greer, "Transition from a Strong-Yet-Brittle to a Stronger-and-Ductile State by Size Reduction of Metallic Glasses, " Nat. Mater., 9 215-219 (2010).
71. R. Raghavan, P. Murali, and U. Ramamurty, "On Factor Influencing the Ductile-to-Brittle Transition in a Bulk Metallic Glass, " Acta Mater., 57 3332-3340 (2009).
72. C. C. Yuan, J. F. Xiang, X. K. Xi, and W. H. Wang, "NMR Signature of Evolution of Ductile-to-Brittle Transition in Bulk Metallic Glasses, " Phys. Rev. Lett., 107 236403 (2011).
73. F. Yuan and L. Huang, "Molecular Dynamics Simulation of Amorphous Silica Under Uniaxial Tension: From Bulk to Nanowire, " J. Non-Cryst. Solids, 358 3481-3487 (2012).
74. A. Grimaldi, M. George, G. Pallares, C. Marlière, and M. Ciccotti, "The Crack Tip: A Nanolab for Studying Confied Liquids, " Phys. Rev. Lett., 100 165505 (2008).
75. G. Pallares, A. Grimaldi, M. George, L. Ponson, and M. Ciccotti, "Quantitative Analysis of Crack Closure Driven by Laplace Pressure in Silica Glass, " J. Am. Ceram. Soc., 94 [8] 2613-2618 (2011).
76. S. M. Wiederhorn, T. Fett, J.-P. Guin, and M. Ciccotti, "Griffith Cracks at the Nanoscale, " Int. J. Appl. Glass Sci., 4 [2] 76-86 (2013).
77. K. Han, M. Ciccotti, and S. Roux, "Measuring Nanoscale Stress Intensity Factors with an Atomic Force Microscope, " Europhys. Lett., 89 [6] 66003 (2010).
78. H. Lee, S. Cho, K. Yoon, and J. Lee, "Glass Thickness and Fragmentation Behavior in Stressed Glasses, " New J. Glass Ceram., 2 116-121 (2012).
79. M. Davydova and S. Uvarov, "Fractal Statistics of Brittle Fragmentation, " Fract. Struct. Integ., 24 60-68 (2013).
80. A. Chateauminois, B. Chabert, J. P. Soulier, and L. Vincent, "Hygrothermal Ageing Effects on the Static Fatigue of Glass/Epoxy Composites, " Composites, 24 547-555 (1993).
81. A. Tandia, K. D. Vargheese, J. C. Mauro, and A. K. Varshneya, "Atomistic Understanding of the Network Dilation Anomaly in Ion-Exchanged Glass, " J. Non-Cryst. Solids, 358 [2] 316-320 (2012).
82. A. Tandia, K. D. Vargheese, and J. C. Mauro, "Elasticity of Ion Stuffing in Chemically Strengthened Glass, " J. Non-Cryst. Solids, 358 [12-13] 1569-1574 (2012).
83. L. Mattos, "Usable Glass Strength Coalition: Patience, Perseverance, and Progress, " Am. Ceram. Soc. Bull., 91 [4] 22-29 (2013).
84. G. D. Quinn, "A History of the Fractography of Glasses and Ceramics, " Fractograp. Glass. Ceram. VI. Ceram. Trans., 230 1-55 (2012).
85. C. M. Jantzen, K. G. Brown, and J. B. Pickett, "Durable Glass for Thousands of Years, " Int. J. Appl. Glass Sci., 1 [1] 38-62 (2010).
86. P. A. Bingham, A. J. Connelly, N. C. Hyatt, and R. J. Hand, "Corrosion of Glass Contact Refractories for the Vitrification of Radioactive Wastes: A Review, " Int. Mater. Rev., 56 [4] 226-242 (2011).
87. J. D. Vienna, J. V. Ryan, S. Gin, and Y. Inagaki, "Current Understanding and Remaining Challenges in Modeling Long-Term Degradation of Borosilicate Nuclear Waste Glasses, " Int. J. Appl. Glass Sci., 4 [4] 283-294 (2013).
88. A. Paul, "Chemical Durability of Glasses: A Thermodynamic Approach, " J. Mat. Sci., 12 2246-2268 (1977).
89. B. Wei, H. Cao, and S. Song, "Tensile Behavior Contrast of Basalt and Glass Fibers After Chemical Treatment, " Mater. Des., 31 4244-4250 (2010).
90. S. Kerisit, J. V. Ryan, and E. M. Pierce, "Monte Carlo Simulations of the Corrosion of Aluminoborosilicate Glasses, " J. Non-Cryst. Solids, 378 273-281 (2013).
91. A. K. Varshneya, Fundamentals of Inorganic Glasses, 2nd edition, Society of Glass Technology, Sheffield, 2006.
92. J. Fabian and P. B. Allen, "Theory of Sound Attenuation in Glasses: The Role of Thermal Vibrations, " Phys. Rev. Lett., 82 1478-1481 (1999).
93. B. Rufflé, G. Guimbretière, E. Courtens, R. Vacher, and G. Monaco, "Glass-Specific Behavior in the Damping of Acousticlike Vibrations, " Phys. Rev. Lett., 96 045502 (2006).
94. B. Rufflé, D. A. Parshin, E. Courtens, and R. Vacher, "Boson Peak and its Relation to Acoustic Attenuation in Glasses, " Phys. Rev. Lett., 100 015501 (2008).
95. E. Rat, et al., "Anharmonic Versus Relaxational Sound Damping in Glasses: I. Brillouin Scattering from Densified Silica, " Phys. Rev. B., 72 214204 (2005).
96. R. Vacher, E. Courtens, and M. Foret, "Anharmoic Versus Relaxational Sound Damping in Glasses. II. Vitreous Silica, " Phys. Rev. B., 72 214205 (2005).
97. C. Kittel, "Interpretation of the Thermal Conductivity of Glasses, " Phys. Rev., 75 972-974 (1949).
98. R. C. Zeller and R. O. Pohl, "Thermal Conductivity and Specific Heat of Noncrystalline Solids, " Phys. Rev. B., 4 2029-2041 (1971).
99. M. P. Zaitlin and A. C. Anderson, "Thermal Conductivity of Borosilicate Glass, " Phys. Rev. Lett., 33 1158-1161 (1974).
100. C. C. Yu and J. J. Freeman, "Thermal Conductivity and Specific Heat of Glasses, " Phys. Rev. B., 36 7620-7624 (1987).
101. J. L. Feldman, M. D. Kluge, P. B. Allen, and F. Wooten, "Thermal Conductivity and Localization in Glasses: Numerical Study of a Model of Amorphous Silicon, " Phys. Rev. B., 48 12589-12602 (1993).
102. S. Wang and J. Qiu, "Enhancing Thermal Conductivity of Glass Fiber/Polymer Composites Through Carbon Nanotubes Incorporation, " Compos. Part B. Eng., 41 533-536 (2010).
103. A. G. Fedorov and L. Pilon, "Glass Foams: Formation, Transport Properties, and Heat, Mass, and Radiation Transfer, " J. Non-Cryst. Solids, 311 154-173 (2002).
104. J. Ballato and P. Dragic, "Rethinking Optical Fiber: New Demands, Old Glasses, " J. Am. Ceram. Soc., 96 [9] 2675-2692 (2013).
105. M. Guignard, L. Albrecht, and J. W. Zwanziger, "Zero-Stress Optic Glass without Lead, " Chem. Mater., 19 [2] 286-290 (2007).
106. M. M. Smedskjaer, M. Potuzak, X. Guo, and J. C. Mauro, "Compositional Control of the Photoelastic Response of Silicate Glasses, " Opt. Mater., 35 2436-2439 (2013).
107. H. Li, M. J. Davis, A. J. Marker III, and J. S. Hayden, "Glass and Light, " Int. J. Appl. Glass Sci., 1 [1] 63-73 (2010).
108. K. Richardson, D. Krol, and K. Hirao, "Glasses for Photonic Applications, " Int. J. Appl. Glass Sci., 1 [1] 74-86 (2010).
109. G. Tao, A. F. Abouraddy, and A. M. Stolyarov, "Multimaterial Fibers, " Int. J. Appl. Glass Sci., 3 [4] 349-368 (2012).
110. D. Litzkendorf, et al., "Study of Lanthanum Aluminum Silicate Glasses for Passive and Active Optical Fibers, " Int. J. Appl. Glass Sci., 3 [4] 321-331 (2012).
111. L. L. Hench and D. E. Clark, "Physical Chemistry of Glass Surfaces, " J. Non-Cryst. Solids, 28 83-105 (1978).
112. C. G. Pantano, D. B. Dove, and G. Y. Onoda, "Glass Surface Analysis by Auger Electron Spectroscopy, " J. Non-Cryst. Solids, 19 41-53 (1975).
113. E. A. Leed and C. G. Pantano, "Computer Modeling of Water Adsorption on Silica and Silicate Glass Fracture Surfaces, " J. Non-Cryst. Solids, 325 48-60 (2003).
114. C. G. Pantano, "What Do We Know About Glass Surfaces?" 61st Conference on Glass Problems: Ceram. Eng. Sci. Proc., 244 137 (2009).
115. M. M. Smedskjaer, J. C. Mauro, S. Sen, J. Deubener, and Y. Yue, "Impact of Network Topology on Cationic Diffusion and Hardness of Borate Glass Surfaces, " J. Chem. Phys., 133 154509 (2010).
116. P. F. McMillan, "Polyamorphic Transformations in Liquids and Glasses, " J. Mater. Chem., 14 1506-1512 (2004).
117. P. F. McMillan, M. Wilson, M. C. Wilding, D. Daisenberger, M. Mezouar, and G. N. Greaves, "Polyamorphism and Liquid-Liquid Phase Transitions: Challenges for Experiment and Theory, " J. Phys. Condens. Matter, 19 [41] 415101 (2007).
118. O. Mishima and H. E. Stanley, "The Relationship Between Liquid, Supercooled and Glassy Water, " Nature, 396 329-335 (1998).
119. O. Mishima and Y. Suzuki, "Propagation of the Polyamorphic Transition of Ice and the Liquid-Liquid Critical Point, " Nature, 419 599-603 (2002).
120. S. Klotz, et al., "Nature of the Polyamorphic Transition in Ice Under Pressure, " Phys. Rev. Lett., 94 025506 (2005).
121. A. Ha, I. Cohen, X. Zhao, M. Lee, and D. Kivelson, "Supercooled Liquids and Polyamorphism, " J. Phys. Chem., 100 [1] 1-4 (1996).
122. H. W. Sheng, et al., "Polyamorphism in a Metallic Glass, " Nat. Mater., 6 192-197 (2007).
123. I. Saika-Voivod, F. Sciortino, and P. H. Poole, "Computer Simulations of Liquid Silica: Equation of State and Liquid-Liquid Phase Transition, " Phys. Rev. E, 63 011202 (2000).
124. L. Huang, L. Duffrène, and J. Kieffer, "Structural Transitions in Silica Glass: Thermo-Mechanical Anomalies and Polyamorphism, " J. Non-Cryst. Solids, 349 1-9 (2004).
125. M. Paluch, J. Ziolo, S. J. Rzoska, and P. Habdas, "High-Pressure and Temperature Dependence of Dielectric Relaxation in Supercooled Di-isobutyl Phthalate, " Phys. Rev. E, 54 4008-4010 (1996).
126. D. L. Porter, A. G. Evans, and A. H. Heuer, "Transformation-Toughening in Partially-Stabilized-Zirconia (PSZ), " Acta Metal, 27 1649-1654 (1979).
127. S. Reibstein, et al., "Structural Heterogeneity and Pressure-Relaxation in Compressed Borosilicate Glasses by in situ Small Angle X-ray Scattering, " J. Chem. Phys., 134 204502 (2011).
128. S. Striepe, et al., "Elastic and Micromechanical Properties of Isostatically Compressed Soda-Lime-Borate Glasses, " J. Non-Cryst. Solids, 364 44-52 (2013).
129. W. Höland, and G. H. Beall, Glass-Ceramic Technology, 2nd edition, Wiley, Hoboken, 2012.
130. E. D. Zanotto, "A Bright Future for Glass-Ceramics, " Am. Ceram. Soc. Bull., 89 [8] 19-27 (2010).
131. T. Komatsu and T. Honma, "Optical Active Nano-Glass-Ceramics, " Int. J. Appl. Glass Sci., 4 [2] 125-135 (2013).
132. J. R. Jones and A. G. Clare, Bio-Glasses, Wiley, West Sussex, 2012.
133. L. L. Hench, D. E. Day, W. Höland, and V. M. Rheinberger, "Glass and Medicine, " Int. J. Appl. Glass Sci., 1 [1] 104-107 (2010).
134. M. Erol-Taygun, K. Zheng, and A. R. Boccacchini, "Nanoscale Bioactive Glasses in Medical Applications, " Int. J. Appl. Glass Sci., 4 [2] 136-148 (2013).
135. I. Izquierdo-Barba, A. J. Salinas, and M. Vallet-Regi, "Bioactive Glasses: From Macro to Nano, " Int. J. Appl. Glass Sci., 4 [2] 149-161 (2013).
136. M. N. Rahaman, et al., "Bioactive Glass in Tissue Engineering, " Acta Biomat., 7 [6] 2355-2373 (2011).
137. Q. Fu, E. Saiz, M. N. Rahaman, and A. P. Tomsia, "Bioactive Glass Scaffolds for Bone Tissue Engineering: State of the Art and Future Perspectives, " Mat. Sci. Eng. C, 31 [7] 1245-1256 (2011).
138. L. L. Hench and I. Thompson, "Twenty-First Century Challenges for Biomaterials, " J. R. Soc. Interface, 7 S379-S391 (2010).
139. H. S. Norville, K. W. King, and J. L. Swofford, "Behavior and Strength of Laminated Glass, " J. Eng. Mech., 124 [1] 46-53 (1998).
140. R. A. Behr, J. E. Minor, and H. S. Norville, "Structural Behavior of Architectural Laminated Glass, " J. Struct. Eng., 119 [1] 202-222 (1993).
141. D. Alhazov and E. Zussman, "Study of the Energy Absorption Capabilities of Laminated Glass Using Carbon Nanotubes, " Compos. Sci. Technol., 72 681-687 (2012).
142. P. A. Hooper, R. A. M. Sukhram, B. R. K. Blackman, and J. P. Dear, "On the Blast Resistance of Laminated Glass, " Int. J. Solids Struct., 49 899-918 (2012).
143. G. H. Beall and L. R. Pinckney, "Nanophase Glass-Ceramics, " J. Am. Ceram. Soc., 82 [1] 5-16 (1999).
144. L. R. Pinckney, "Transparent, High Strain Point Spinel Glass-Ceramics, " J. Non-Cryst. Solids, 255 171-177 (1999).
145. G. S. Rohrer, "Challenges in Ceramic Science: A Report from the Workshop on Emerging Research Areas in Ceramic Science, " J. Am. Ceram. Soc., 95 [12] 3699-3712 (2012).
146. J. P. DeWald, C. J. Arcoria, and J. L. Ferracane, "Evaluation of Glass-Cermet Cores Under Cast Crowns, " Dental Mater., 6 129-132 (1990).
147. Y. Yao, et al., "An Innovative Energy-Saving In-Flight Melting Technology and its Application to Glass Production, " Sci. Technol. Adv. Mater., 9 025013 (2008).
148. T. Watanabe, K. Yatsuda, Y. Yao, T. Yano, and T. Matuura, "Innovative In-Flight Glass-Melting Technology Using Thermal Plasmas, " Pure Appl. Chem., 82 [6] 1337-1351 (2010).
149. S. H. Henager, P. Hrma, K. J. Swearingen, M. J. Schweiger, J. Marcial, and N. E. TeGrotenhuis, "Conversion of Batch to Molten Glass, I: Volume Expansion, " J. Non-Cryst. Solids, 357 829-835 (2011).
150. P. Hrma, J. Marcial, K. J. Swearingen, S. H. Henager, M. J. Schweiger, and N. E. TeGrotenhuis, "Conversion of Batch to Molten Glass, II: Dissolution of Quartz Particles, " J. Non-Cryst. Solids, 357 820-828 (2011).
151. R. Pokorny, D. A. Pierce, and P. Hrma, "Melting of Glass Batch: Model for Multiple Overlapping Gas-Evolving Reactions, " Thermochim. Acta, 541 8-14 (2012).
152. R. G. C. Beerkens, "Modeling the Kinetics of Volatilization from Glass Melts, " J. Am. Ceram. Soc., 84 1952-1960 (2001).
153. R. G. C. Beerkens, "Sulfate Decomposition and Sodium Oxide Activity in Soda-Lime-Silica Glass Melts, " J. Am. Ceram. Soc., 86 1893-1899 (2003).
154. R. G. C. Beerkens and J. van der Schaaf, "Gas Release and Foam Formation During Melting and Fining of Glass, " J. Am. Ceram. Soc., 89 [1] 24-35 (2006).
155. H. Müller-Simon, "Fining of Glass Melts, " Rev. Mineral. Geochem., 73 337-361 (2011).
156. H. Mase and K. Oda, "Mathematical Model of Glass Tank Furnace with Batch Melting Process, " J. Non-Cryst. Solids, 38-39 807-812 (1980).
157. R. Viskanta, "Review of Three-Dimensional Mathematical Modeling of Glass Melting, " J. Non-Cryst. Solids, 177 347-362 (1994).
158. A. Abbassi and K. Khoshmanesh, "Numerical Simulation and Experimental Analysis of an Industrial Glass Melting Furnace, " Appl. Therm. Eng., 28 450-459 (2008).
159. Z. Feng, D. Li, G. Qin, and S. Liu, "Study of the Float Glass Melting Process: Combining Fluid Dynamics Simulation and Glass Homogeneity Inspection, " J. Am. Ceram. Soc., 91 [10] 3229-3234 (2008).