Tellurite And Fluorotellurite Glasses For Active And Passive

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8. Fibre drawing; MDO 373 2004 Meeting incorporating the XIVth International Symposium on Non-Oxide and Novel Optical Glasses, Cape Canaveral, Florida, USA, 2004. [14] K. Ito, C. T. Moynihan, and C. A. Angell, "Thermodynamic determination of fragility in liquids and a fragile-to-strong liquid transition in water," Nature, vol. 398, pp. 492-495, 1999. [15] C. A. Angell, "Spectroscopy simulation and scattering, and the medium range order problem in glass," Journal of Non-Crystalline Solids, vol. 73, pp. 1-17, 1985. [16] S. W. Martin and C. A. Angell, "On the glass transition and viscosity of P2O5," Journal of Physical Chemistry, vol. 90, pp. 6736-6740, 1986. [17] S. English, "The effect of various constituents on the viscosity of glass near its annealing temperature," Journal of the Society of Glass Technology, vol. 7, pp. 25-45, 1923. [18] J. Wang, E. Vogel, and E. Snitzer, "Tellurite glass: a new candidate for fiber devices," Optical Materials, vol. 3, pp. 187-203, 1994. [19] M. Braglia, "Viscosity of halide glasses," in Properties, processing and applications of glass and rare earth-doped glasses for optical fibres, D. Hewak, Ed. Exeter: INSPEC, 1988, pp. 194-201. [20] A. Jha and J. M. Parker, "Viscosity models for fluorozirconate and fluoroaluminate glasses," Physics and Chemistry of Glasses, vol. 30, pp. 220-228, 1989. [21] T. Komatsu, K. Aida, T. Honma, Y. Benino, and R. Sato, "Decoupling between enthalpy relaxation and viscous flow and its structural origin in fragile oxide glass-forming liquids," Journal of the American Ceramic Society, vol. 85, pp. 193-199, 2002. [22] T. Komatsu, R. Ike, R. Sato, and K. Matusita, "Mixed-alkali effect in tellurite glasses and change in fragility," Physics and Chemistry of Glasses, vol. 36, pp. 216-221, 1995. [23] T. Kosuge, Y. Benino, V. Dimitrov, R. Sato, and T. Komatsu, "Thermal stability and heat capacity changes at the glass transition in K2O-WO3-TeO2 glasses," Journal of Non-Crystalline Solids, vol. 242, pp. 154-164, 1998. [24] T. Watanabe, Y. Benino, and T. Komatsu, "Change in Vickers hardness at the glass transition region for fragile and strong glasses," Journal of Non-Crystalline Solids, vol. 286, pp. 141-145, 2001.

8. Fibre drawing; MDO 374 [25] D. M. Zhu, C. S. Ray, W. C. Zhou, and D. E. Day, "Glass transition and fragility of Na2O-TeO2 glasses," Journal of Non-Crystalline Solids, vol. 319, pp. 247-256, 2003. [26] J. E. Shelby, Introduction to glass science and technology. Cambridge: RSC Paperbacks, 1997. [27] W. Vogel, Glass chemistry, 2nd ed. New York: Springer-Verlag, 1994. [28] M. L. Ovecoglu, G. Ozen, B. Demirata, and A. Genc, "Microstructural characterization and crystallization kinetics of (1-x)TeO2-xLiCl (x=0.6-0.4 mol) glasses," Journal of the European Ceramic Society, vol. 21, pp. 177-183, 2001. [29] H. Burger, I. Gugov, U. Grunke, J. Kraus, and B. Manzanares-Taylor, "Preforms for large optical bandwidth amplifier fibres," Glass Science and Technology, vol. 75, pp. 261-264, 2002. [30] H. G. Kim, T. Komatsu, R. Sato, and K. Matusita, "Fiber drawing of LiNbO3doped mixed-alkali tellurite glasses," Journal of the Ceramic Society of Japan, vol. 103, pp. 1073-1076, 1995. [31] S. Shen, A. Jha, E. Zhang, and S. J. Wilson, "Compositional effects and spectroscopy of rare earths (Er 3+ , Tm 3+ , and Nd 3+ ) in tellurite glasses," Comptes Rendus Chimie, vol. 5, pp. 921-938, 2002. [32] F. T. Wallenberger, N. E. Weston, and D. B. Sherman, "Infrared optical tellurite glass fibers," Journal of Non-Crystalline Solids, vol. 144, pp. 107-110, 1992. [33] R. J. Ryder and G. E. Rindone, "Color and light scattering of platinum in some lead glasses," Journal of the American Ceramic Society, vol. 41, pp. 415-422, 1958. [34] A. Paul and A. N. Tiwari, "Optical absorption of platinum(IV) in Na2O-B2O3 and Na2O-NaCl-B2O3 glasses," Physics and Chemistry of Glasses, vol. 14, pp. 69-72, 1973. [35] M. Karabulut, G. K. Marasinghe, C. A. Click, E. Metwalli, R. K. Brow, C. H. Booth, J. J. Bucher, D. K. Shuh, T. I. Suratwala, and J. H. Campbell, "XAFS investigation of platinum impurities in phosphate glasses," Journal of the American Ceramic Society, vol. 85, pp. 1093-1099, 2002.

Page 1 and 2: TELLURITE AND FLUOROTELLURITE GLASS

Page 3 and 4: Abstract Glasses systems based on T

Page 5 and 6: Contents; MDO i Contents Contents i

Page 7 and 8: Contents; MDO iii 6.1.2.1. Method a

Page 9 and 10: Glossary; MDO Glossary aM = partial

Page 11 and 12: Glossary; MDO λ = wavelength λn =

Page 13 and 14: Glossary; MDO Ψ = complex dielectr

Page 15 and 16: 1. Introduction; MDO 2 communicatio

Page 17 and 18: 1. Introduction; MDO 4 Infrared tra

Page 19 and 20: 1. Introduction; MDO 6 1.4. Thesis

Page 21 and 22: 1. Introduction; MDO 8 [14] J. E. S

Page 23 and 24: 2. Literature review; MDO 10 one of

Page 25 and 26: 2. Literature review; MDO 12 superc

Page 27 and 28: 2. Literature review; MDO 14 2.2.2.

Page 29 and 30: 2. Literature review; MDO 16 phenom

Page 31 and 32: 2. Literature review; MDO 18 tenden

Page 33 and 34: 2. Literature review; MDO 20 crysta

Page 35 and 36: 2. Literature review; MDO 22 the Za


Page 39 and 40: 2. Literature review; MDO 26 Champa

Page 41 and 42: 2. Literature review; MDO 28 the ad

Page 43 and 44: 2. Literature review; MDO 30 (a) (b

Page 45 and 46: 2. Literature review; MDO 32 showed

Page 47 and 48: 2. Literature review; MDO 34 absorp

Page 49 and 50: 2. Literature review; MDO 36 sharp

Page 51 and 52: 2. Literature review; MDO 38 near f

Page 53 and 54: 2. Literature review; MDO 40 where

Page 55 and 56: 2. Literature review; MDO 42 Transm

Page 57 and 58: 2. Literature review; MDO 44 origin

Page 59 and 60: 2. Literature review; MDO 46 4 α =

Page 61 and 62: 2. Literature review; MDO 48 Bragli

Page 63 and 64: 2. Literature review; MDO 50 It can

Page 65 and 66: 2. Literature review; MDO 52 and su

Page 67 and 68: 2. Literature review; MDO 54 be bro


Page 71 and 72: 2. Literature review; MDO 58 Table


Page 75 and 76: 2. Literature review; MDO 62 [20] J

Page 77 and 78: 2. Literature review; MDO 64 [47] S

Page 79 and 80: 3. Glass batching and melting; MDO








Page 95 and 96: 4. Thermal properties and glass sta


























Page 147 and 148: 5. Crystallisation studies; MDO 134
















Page 179 and 180: 6. Optical properties; MDO 166 75-5

Page 181 and 182: 6. Optical properties; MDO 168 Fig.

Page 183 and 184: 6. Optical properties; MDO 170 In r

Page 185 and 186: 6. Optical properties; MDO 172 wher


Page 189 and 190: 6. Optical properties; MDO 176 Abso

Page 191 and 192: 6. Optical properties; MDO 178 ener

Page 193 and 194: 6. Optical properties; MDO 180 6.1.

Page 195 and 196: 6. Optical properties; MDO 182 ( n


Page 199 and 200: 6. Optical properties; MDO 186 %),

Page 201 and 202: 6. Optical properties; MDO 188 Tabl




Page 209 and 210: Percentage (%) 80 70 60 50 40 30 20




Page 217 and 218: 6. Optical properties; MDO 204 Loss


Page 221 and 222: 6. Optical properties; MDO 208 Tabl



Page 227 and 228: 6. Optical properties; MDO 214 Loss




Page 235 and 236: Refractive index, n , at 632.8 nm 6



Page 241 and 242: 6. Optical properties; MDO 228 tell

Page 243 and 244: 6. Optical properties; MDO 230 mole

Page 245 and 246: 6. Optical properties; MDO 232 occu

Page 247 and 248: 6. Optical properties; MDO 234 The

Page 249 and 250: 6. Optical properties; MDO 236 addi

Page 251 and 252: 6. Optical properties; MDO 238 an o

Page 253 and 254: 6. Optical properties; MDO 240 30 m


Page 257 and 258: 6. Optical properties; MDO 244 zinc

Page 259 and 260: 6. Optical properties; MDO 246 [4]

Page 261 and 262: 6. Optical properties; MDO 248 [32]

Page 263 and 264: 7. Surface properties; MDO 250 7.1.

Page 265 and 266: 7. Surface properties; MDO 252 For

Page 267 and 268: 7. Surface properties; MDO 254 can

Page 269 and 270: 7. Surface properties; MDO 256 wher

Page 271 and 272: 7. Surface properties; MDO 258 etch

Page 273 and 274: 7. Surface properties; MDO 260 Elem

Page 275 and 276: 7. Surface properties; MDO 262 All

Page 277 and 278: 7. Surface properties; MDO 264 beco

Page 279 and 280: 7. Surface properties; MDO 266 prov

Page 281 and 282: 7. Surface properties; MDO 268 cont

Page 283 and 284: 7. Surface properties; MDO 270 LaB6

Page 285 and 286: 7. Surface properties; MDO 272 7.2.

Page 287 and 288: 7. Surface properties; MDO 274 Tabl

Page 289 and 290: 7. Surface properties; MDO 276 This

Page 291 and 292: 7. Surface properties; MDO 278 It c

Page 293 and 294: 7. Surface properties; MDO 280 Fig.

Page 295 and 296: 7. Surface properties; MDO 282 CPS



Page 301 and 302: 7. Surface properties; MDO 288 samp

Page 303 and 304: 7. Surface properties; MDO 290 20

Page 305 and 306: 7. Surface properties; MDO 292 20

Page 307 and 308: 7. Surface properties; MDO 294 Wt.

Page 309 and 310: 7. Surface properties; MDO 296 It c


Page 313 and 314: 7. Surface properties; MDO 300 The

Page 315 and 316: 7. Surface properties; MDO 302 Wt.

Page 317 and 318: 7. Surface properties; MDO 304 All

Page 319 and 320: 7. Surface properties; MDO 306 The

Page 321 and 322: [Zn(OH,F)F] / mol. % 7. Surface pro

Page 323 and 324: 7. Surface properties; MDO 310 bind

Page 325 and 326: 7. Surface properties; MDO 312 ZnF2

Page 327 and 328: 7. Surface properties; MDO 314 clea

Page 329 and 330: 7. Surface properties; MDO 316 have


Page 333 and 334: 7. Surface properties; MDO 320 quan

Page 335 and 336: 7. Surface properties; MDO 322 ∫

Page 337 and 338: 7. Surface properties; MDO 324 This

Page 339 and 340: 7. Surface properties; MDO 326 Ther

Page 341 and 342: 7. Surface properties; MDO 328 [2]

Page 343 and 344: 8. Fibre drawing; MDO 330 8. Fibre

Page 345 and 346: 8. Fibre drawing; MDO 332 The data

Page 347 and 348: 8. Fibre drawing; MDO 334 Table (8.

Page 349 and 350: Preform 8. Fibre drawing; MDO 336 S

Page 351 and 352: 8. Fibre drawing; MDO 338 (a) (b) F

Page 353 and 354: 8. Fibre drawing; MDO 340 Log10(η)

Page 355 and 356: 8. Fibre drawing; MDO 342 sectioned

Page 357 and 358: 8. Fibre drawing; MDO 344 Fig. (8.9



Page 363 and 364: 8. Fibre drawing; MDO 350 Crystals

Page 365 and 366: 8. Fibre drawing; MDO 352 8.2.4. Op

Page 367 and 368: 8. Fibre drawing; MDO 354 Table (8.

Page 369 and 370: 8. Fibre drawing; MDO 356 confirmed

Page 371 and 372: 8. Fibre drawing; MDO 358 Log10(η)

Page 373 and 374: 8. Fibre drawing; MDO 360 It can be

Page 375 and 376: 8. Fibre drawing; MDO 362 undercool

Page 377 and 378: 8. Fibre drawing; MDO 364 1. 2. 3.

Page 379 and 380: 8. Fibre drawing; MDO 366 cross-sha

Page 381 and 382: 8. Fibre drawing; MDO 368 A small n

Page 383 and 384: 8. Fibre drawing; MDO 370 particles

Page 385: 8. Fibre drawing; MDO 372 8.5. Refe

Page 389 and 390: 9. Conclusions; MDO 376 optical bas

Page 391 and 392: 9. Conclusions; MDO 378 • The as-

Page 393 and 394: 9. Conclusions; MDO 380 9.3. Optica

Page 395 and 396: 9. Conclusions; MDO 382 • For fib

Page 397 and 398: 9. Conclusions; MDO 384 edge across

Page 399 and 400: 9. Conclusions; MDO 386 • For gla

Page 401 and 402: 9. Conclusions; MDO 388 • The Ag

Page 403 and 404: 9. Conclusions; MDO 390 • Increas

Page 405 and 406: 9. Conclusions; MDO 392 [5] I. Shal

Page 407 and 408: 10. Future work; MDO 394 Fig. (10.1

Page 409 and 410: Temperature / o C 10. Future work;

fibre

optical

tellurite

peak

melting

properties

absorption

bands

oxide

fluorotellurite

active

passive

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