Glass Science and Glassmaking: A Personal Perspective

International Journal of Applied Glass Science

Volumn 1, Issue 1, 2010, Pages 3-15

  Roy, Rustum ^a,b  

^a ARIZONA STATE UNIVERSITY   (United States)

^b PENNSYLVANIA STATE UNIVERSITY   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

GLASS SCIENCE; GLASSY STATE; NANOMATERIAL; PERSONAL PERSPECTIVE; SMALL PARTICLES;

GLASS CERAMICS;

EID: 78649661879     PISSN: 20411286     EISSN: 20411294     Source Type: Journal    
DOI: 10.1111/j.2041-1294.2010.00002.x     Document Type: Article

References (46)

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2. R. Roy, "Multiple Ion Substitution in the Perovskite Lattice, " J. Am. Ceram. Soc., 37, 581-588 (1954).
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15. D. Stookey U.S. Patent 2, 920, 971: Filed June 4, 1956. Issued January 12, 1960. Also see U.S. Court of Appeals. Third Circuit October 20, 1967. Reference to Case H: 374F2d473.
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25. G. C. Vezzoli, F. Dachille, and R. Roy, "The Melting Curve of Sulfur to 31 kbars, " Inorg. Chem., 8, 2658-2661 (1969).
26. G. C. Vezzoli, F. Dachille, and R. Roy, "Technique for Detecting High-Pressure Transitions in Insulators, " J. Am. Ceram. Soc., 54, 221-222 (1971).
27. G. C. Vezzoli, F. Dachille, and R. Roy, "High-Pressure Studies of Polymerization in Sulfur, " J. Polym. Sci., 7 [Part A-1] 1557-1566 (1969).
28. R. Roy, W. A. Till, I. Bell, and M. R. Hoover, "The Structure of Liquid Water; Novel Insights from Materials Research; Potential Relevance to Homeopathy, " Mater. Res. Innov., 9 [4] 577-608 (2005).
29. M. L. Rao, R. Roy, and I. Bell, "Characterization of the Structure of Ultra Dilute Sols with Remarkable Biological Properties, " Mater. Lett., 62, 1487-1490 (2008).
30. H. E. Stanley, S. V. Buldyrev, M. Campolat, M. Meyer, O. Mishima, M. R. Sadr-Laahijany, A. Scala, and F. W. Starr, "The Puzzling Statistical Physics of Liquid Water, " Phys. A, 257, 213-232 (1998).
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34. C. A. Angell, "Insights into Phases of Liquid Water from Study of Its Unusual Glass-Forming Properties, " Science, 319 [5863] 582-587 (2008).
35. T. Kawamoto, S. Ochiai, and H. Kagi, J. Chem. Phys., 120, 5867 (2004).
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37. R. Roy, D. Agrawal, J. P. Cheng, and M. Mathis, "Microwave Processing: Triumph of Applications-Driven Science in WC-Composites and Ferroic Titanates, " Am. Ceram. Soc., 80, 3-26 (1997).
38. R. Roy, R. D. Peelamedu, C. A. Grimes, and D. Agrawal, "Major Phase Transformations and Magnetic Property Changes Caused by Electromagnetic Fields at Microwave Frequencies, " J. Mater. Res., 17 [12] 3008-3011 (2002).
39. R. Roy, J. Cheng, and D. Agrawal "Microwave Processing in Pure H Fields and Pure E Fields, " United States Patent Number 6, 365, 885, April 2, 2002.
40. R. Roy and D. Agrawal "The New Science of MicrowaveMaterials Interactions: The Role of Separated E and H Fields and its Real World Applications, "Proceedings of the 6th Symposium on Microwave Applications and Related Fields, Oyaki-City, Japan, November 2-4, 2006.
41. R. Roy, R. D. Peelamedu, L. Hurtt, J. P. Cheng, and D. Agrawal, "Definitive Experimental Evidence for Microwave Effects: Radically New Effects of Separated E and H Fields, Such as Decrystallization of Oxides in Seconds, " Mater. Res. Innov., 6, 128-140 (2002).
42. R. Roy, Y. Fang, J. Cheng, and D. Agrawal, "Decrystallizing Solid Crystalline Titania, Without Melting, Using Microwave Magnetic Fields, " J. Am. Ceram. Soc., 88 [6] 1640-1642 (2005).
43. M. Sato, N. Nishi, M. Tanaka, A. Matsubara, S. Takayama, H. Fukushima, M. Ignatenko, R. Roy, D. Agrawal, and J. Fukusima, "Formation of Nano-Domains by Microscopic Thermal Non-Equilibrium Generated in GHz High Frequency Microwave Field, "Proceedings of the 1st Global Congress on Microwave Engineering Applications, Japan, August 2008, 491-494, 2008.
44. M. Sato, T. Mutoh, T. Shimotuma, K. Ida, O. Motojima, M. Fujuwara, S. Takayama, M. Mizuno, S. Obuata, K. Ito, T. Kirai, and T. Shimada, "Recent Developments of Microwave Kilns for Industries in Japan, " Proc of the Third World Congress on Microwave and Radio Frequency Applications, Vol. 281, eds., D. Folz, J. Booske, D. Clark, and J. Gerling ACS Publ, Washington, D.C., 189, 2003.
45. N. Kazuhiro "Innovation of Iron Making by Microwave Heating, "Proceeding of the 1st Global Congress on Microwave Engineering Applications, Japan, August, p. 314, 2008.
46. M. Sato, A. Matsubara, S. Takayama, S. Sudo, O. Motojima, K. Nagata, K. Ishizaki, T. Hayashi, D. Agrawal, and R. Roy, "Experimental Analysis for Thermally Non-Equilibrium State Under Microwave Irradiations-A Greener Process for Steel Making, " Advanced Processing of Metals and Materials, Proceedings of the Sohn International Symposium, eds., F. Kongoli, and G. Reddy publ. TMS, San Diego, CA, 157-170, 2006.