Abstract
This chapter is a review dedicated to recent advances in the science of glass and its application in photonic devices with a straightforward, easy-to-read style. It is important to mention as a starting point that recent advances in this material indicate that the glass network has significant implications both in terms of the optical and mechanical properties and, therefore, the functionalities of glass as a smart material. In this sense, it is essential for the development of new technologies or innovations to better understand the effects of manufacturing techniques to achieve the desired product. In this context, we provide an overview of the history and challenges in glass development, traditional and new manufacturing processes, characterization techniques (structural, thermal, and optical properties), glasses family, and photonic device applications.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Notes
- 1.
2600 B.C., Syrian origin.
- 2.
The term “soft” mainly refers to the relatively low melting and softening temperature, small viscosity, and low hardness of these glasses in comparison with the silica glasses. Additionally, they can offer unique material properties absent in silica glasses including high linear refractive index, high transparency from the near-infrared (NIR) to the mid-infrared (MIR) region, high RE solubility, low phonon energy, etc.
- 3.
The ability of a material to resist elastoplastic deformation.
- 4.
Neodymium Yttrium Aluminum Garnet (NdYAG, NdY3Al5O12) is a synthetic crystalline material of the garnet group.
- 5.
Indium gallium nitride (InGaN, InxGa1 − xN) is a semiconductor material made of a mixture of gallium nitride (GaN) and indium nitride (InN).
- 6.
CCT of correlated color temperature, which is a calculated temperature for a type of light emitted by a blackbody radiator.
References
Edwards, K. L., Axinte, E., & Tabacaru, L. L. (2013). Materials and Design, 50, 713.
Brow, R. K., & Schmitt, M. L. (2009). Journal of the European Ceramic Society, 29, 1193.
Varshneya, A. K., & Mauro, J. C. (2019). Fundamentals of inorganic glasses (3rd edn.). Elsevier B.V.
Zachariasen, W. H. (1932). Journal of the American Chemical Society, 54, 3841.
Ikushima, A. J., Fujiwara, T., & Saito, K. (2000). Journal of Applied Physics, 88, 1201.
Bengisu, M. (2016). Journal of Materials Science, 51, 2199.
Seddon, A. B. (1995). Journal of Non-Crystalline Solids, 184, 44.
Tressaud, A. (2010). Functionalized inorganic fluorides: synthesis, characterization & properties of nanostructured solids. Wiley.
Jha, A., Richards, B., Jose, G., Teddy-Fernandez, T., Joshi, P., Jiang, X., & Lousteau, J. (2012). Progress in Materials Science, 57, 1426.
Martin, J. D. (2006). In H. Li, C. S. Ray, D. M. Strachan, R. Weber & Y. Yue (Eds.), Melt chemistry, relaxation, solidification kinetics of glasses (pp. 57–67). Wiley.
Brow, R. K. (2000). Journal of Non-Crystalline Solids, 263, 1.
El-Mallawany, R. A. H. (2012). Tellurite glasses handbook (2nd edn.). CRC PRESS.
Ngai, K. L. (2005). Journal of Non-Crystalline Solids, 351, 2635.
Wildgoose, D. G., Johnson, A., & Winstanley, R. B. (2004). Journal of Prosthetic Dentistry, 91, 136.
Stern, E. M. (1999). American Journal of Archaeology, 103, 441.
Qiao, A., Bennett, T. D., Tao, H., Krajnc, A., Mali, G., Doherty, C. M., Thornton, A. W., Mauro, J. C., Greaves, G. N., & Yue, Y. (2018). Science Advances, 4, 6827.
Jiusti, J., Zanotto, E. D., Cassar, D. R., & Andreeta, M. R. B. (2020). Journal of the American Ceramic Society, 103, 921.
Hannon, A. C. (2016). Journal of Non-Crystalline Solids, 451, 56.
Khurshid, Z., Husain, S., Alotaibi, H., Rehman, R., Zafar, M. S., Farooq, I., & Khan, A. S. (2019). In G. Kaur (Ed.), Woodhead Publishing Series in Biomaterials (pp. 497–519). Woodhead Publishing.
Ma, Y., Su, H., Zhang, Z., Wan, R., Li, S., Peng, B., & Wang, P. (2021). Ceramics International, 47, 22468.
Zhang, J., Zhang, C., Zhang, X., Li, Z., He, A., Song, J., & Chang, C. (2021). Journal of Alloys and Compounds, 866, 158991.
Shimoda, M., Uchida, M., Hayakawa, T., & Thomas, P. (2017). Ceramics International, 43, 2962.
Wang, R., Zhang, J., Zhao, H., Wang, X., Jia, S., Guo, H., Dai, S., Zhang, P., Brambilla, G., Wang, S., & Wang, P. (2020). Journal of Luminescence, 225, 117363.
Kuhn, S., Tiegel, M., Herrmann, A., Körner, J., Seifert, R., Yue, F., Klöpfel, D., Hein, J., Kaluza, M. C., & Rüssel, C. (2015). Optical Materials Express, 5, 430.
Fan, X., Kuan, P., Li, K., Zhang, L., Li, D., & Hu, L. (2015). Optical Materials Express, 5, 1356.
Cai, M., Lu, Y., Cao, R., Tian, Y., Xu, S., & Zhang, J. (2016). Optical Materials (Amst), 57, 236.
Arepalli, S. K., Tripathi, H., Vyas, V. K., Jain, S., Suman, S. K., Pyare, R., & Singh, S. P. (2015). Materials Science and Engineering C, 49, 549.
Li, M. J., & Hayashi, T. (2019). In Optical fiber telecommunications VII (pp. 3–50). Elsevier Inc.
Lane, J. M. D. (2015). Physical Review E, 92, 012320.
Sanditov, D. S., & Ojovan, M. I. (2017). Physica B Comprises all Condensed Matter, 523, 96.
Mahato, B., Babarinde, V. O., Abaimov, S. G., Lomov, S. V., & Akhatov, I. (2020). Polymer Composites, 41, 1310.
Li, X., Song, W., Yang, K., Krishnan, N. M. A., Wang, B., Smedskjaer, M. M., Mauro, J. C., Sant, G., Balonis, M., & Bauchy, M. (2017). The Journal of Chemical Physics, 147, 074501.
Deshmukh, J. P. K., Kovářík, T., Křenek, T., Docheva, D., & Stichb, T. (2020) RSC Advances, 10, 33782.
Enrichi, F., Armellini, C., Belmokhtar, S., Bouajaj, A., Chiappini, A., Ferrari, M., Quandt, A., Righini, G. C., Vomiero, A., & Zur, L. (2018). Journal of Luminescence, 193, 44.
Almeida, R. M. (2020). In R. Almeida, A. Martucci, L. Santos, & R. E. R. Hernández (Eds.), Sol-gel derived optical and photonic materials (1st edn., pp. 1–6). Elsevier Inc.
Lepry, W. C., & Nazha, S. N. (2021). Advanced NanoBiomed Research, 1, 2000055.
Danks, A. E., Hall, S. R., & Schnepp, Z. (2016). Materials Horizons, 3, 91.
Diba, A. R. B. M. (2014). In T. C. N. Baltzer (Ed.), Precious metals for biomedical applications (pp. 177–211). Woodhead Publishing.
Ciriminna, R., Fidalgo, A., Pandarus, V., Béland, F., Ilharco, L. M., & Pagliaro, M. (2013). Chemical Reviews, 113, 6592.
Bagus, P. S., Ilton, E. S., & Nelin, C. J. (2013). Surface Science Reports, 68, 273.
Greczynski, G., & Hultman, L. (2021). Scientific Reports, 11, 1.
Greczynski, G., & Hultman, L. (2020). Angewandte Chemie International Edition, 59, 5002.
Nukui, A., Taniguchi, T., & Miyata, M. (2001). Journal of Non-Crystalline Solids, 293–295, 255.
Yadav, A. K., & Singh, P. (2015). RSC Advances, 5, 67583.
Elliott, S. R. (1991). Nature, 354, 445.
Dalby, K. N., Nesbitt, H. W., Zakaznova-Herzog, V. P., & King, P. L. (2007). Geochimica et Cosmochimica Acta, 71, 4297.
McMillan, P. (1984). American Mineralogist, 69, 622.
Heili, M., Poumellec, B., Burov, E., Gonnet, C., Le Losq, C., Neuville, D. R., & Lancry, M. (2016). Journal of Materials Science, 51, 1659.
Menczel, J. D., & Kohl, W. S. (2020). In Thermal analysis of textiles and fibers (pp. 17–69). LTD.
Liu, H., Ma, J., Gong, J., & Xu, J. (2015). Journal of Non-Crystalline Solids, 419, 92.
Koontz, E. (2019). In E. Koontz (Ed.), Springer handbook of glass (pp. 853–878). Springer.
Tiegel, M., Hosseinabadi, R., Kuhn, S., Herrmann, A., & Rüssel, C. (2015). Ceramics International, 41, 7267.
Rammah, Y. S., Olarinoye, I. O., El-Agawany, F. I., El-Adawy, A., Gamal, A., & Yousef, E. S. (2020). Ceramics International, 46, 25440.
Wang, J., Ruan, H., Wang, X., & Wan, J. (2018). Journal of Non-Crystalline Solids, 500, 181.
B. Karmakar, in B. Karmakar, K. Rademann & A. L. Stepanov (Eds.), Glass nanocomposites: Synthesis, properties and applications (pp. 3–53). Elsevier Inc.
Griffiths, D. J. (2017). Introduction to electrodynamics. Pearson Cambridge University Press.
Fowles, G. R. (1989). Introduction to modern optics. Dover Publications.
Sangwaranatee, N., Tuscharoen, S., Kim, H. J., & Kaewkhao, J. (2018). Materials Today: Proceedings, 5, 15061.
Fang, Y., Furniss, D., Jayasuriya, D., Parnell, H., Crane, R., Tang, Z. Q., Barney, E., Canedy, C. L., Kim, C. S., Kim, M., Merritt, C. D., Bewley, W. W., Vurgaftman, I., Meyer, J. R., Seddon, A. B., & Benson, T. M. (2019). Optical Materials Express, 9, 2022.
Hu, Y., Lv, J., & Hao, Q. (2021). Sensors, 21, 2421.
Goodman, A. M. (1978). Applied Optics, 17, 2779.
Gomes, J. F., Lima, A. M. O., Sandrini, M., Medina, A. N., Steimacher, A., Pedrochi, F., & Barboza, M. J. (2017). Optical Materials (Amst), 66, 211.
Khalid, M., Chen, G. Y., Ebendorff-Heidepreim, H., & Lancaster, D. G. (2021). Scientific Reports, 11, 10742.
Ahmadi, F., Hussin, R., & Ghoshal, S. K. (2021). Optik (Stuttgart), 227, 166000.
Tan, C. Z., & Arndt, J. (2001). In H. S. Nalwa (Ed.), Silicon-based mater. Devices (pp. 51–91). Academic Press.
Dantanarayana, H. G., Abdel-Moneim, N., Tang, Z., Sojka, L., Sujecki, S., Furniss, D., Seddon, A. B., Kubat, I., Bang, O., & Benson, T. M. (2014). Optical Materials Express, 4, 1444.
Fowles, G. R., & Lynch, D. W. (1968). American Journal of Physics, 36, 770.
Wen, X., Tang, G., Yang, Q., Chen, X., Qian, Q., Zhang, Q., & Yang, Z. (2016). Scientific Reports, 6, 20344.
Falci, R. F., Guérineau, T., Delarosbil, J. L., & Messaddeq, Y. (2022). Journal of Luminescence, 249, 119014.
Ogusu, K., Suzuki, K., & Nishio, H. (2006). Optics Letters, 31, 909.
Konstantinov, I., Babeva, T., & Kitova, S. (1998). Applied Optics, 37, 4260.
Eeu, T. Y., Pang, X. G., Leow, T. Q., Zuahiri, I., & Hussin, R. (2014). Advanced Materials Research, 895, 265.
Xia, M., Luo, J., Chen, C., Liu, H., & Tang, J. (2019). Advanced Optical Materials, 7, 1900851.
Fowler, W. B., & Dexter, D. L. (1962). Physical Review, 128, 2154.
Tarelho, L. V. G., Gomes, L., & Ranieri, I. M. (1997). Physical Review B, 56, 14344.
Zhang, Y. (2019). Journal of Semiconductors, 40, 091102.
Krupke, W. F. (1974). IEEE Journal of Quantum Electronics, 10, 450.
Burshtein, A. I. (1972). Sov. Journal of Experimental and Theoretical Physics, 35, 882.
Fan, T. Y. (1994). Optics Letters, 19, 1343.
Dai, S., Sugiyama, A., Hu, L., Liu, Z., Huang, G., & Jiang, Z. (2002). Journal of Non-Crystalline Solids, 311, 138.
Moncorgé, R., Hull, R., Parisi, J., Osgood, R. M., Warlimont, H., Liu, G., & Jacquier, B. (2005). In Spectroscopic properties of rare earths in optical materials (pp. 320–378).
Bodunov, E. N., Antonov, Y. A., & Gamboa, A. L. S. (2017). The Journal of Chemical Physics, 146, 114102.
Delerue, C., Allan, G., Reynaud, C., Guillois, O., Ledoux, G., & Huisken, F. (2006). Physical Review B—Condensed Matter and Materials Physics, 73, 235318.
Yoshimoto, K., Ezura, Y., Ueda, M., Masuno, A., & Inoue, H. (2018). Advanced Optical Materials, 6, 1701283.
Allain, J. Y., Monerie, M., Poignant, H., & Georges, T. (1993). Journal of Non-Crystalline Solids, 161, 270.
Khegai, A., Firstov, S., Riumkin, K., Alyshev, S., Afanasiev, F., Lobanov, A., Guryanov, A., & Melkumov, M. (2020). Optics Express, 28, 29335.
Mai, H. H., Kaydashev, V. E., Tikhomirov, V. K., Janssens, E., Shestakov, M. V., Meledina, M., Turner, S., Van Tendeloo, G., Moshchalkov, V. V., & Lievens, P. (2014). The Journal of Physical Chemistry C, 121, 15995–16002.
Imai, H., Arai, K., Imagawa, H., Hosono, H., Y., & Abe. (1988). Physical Review B, 38, 772.
Payne, S. A., Chase, L. L., Smith, L. K., Kway, W. L., & Wyers, W. F. (1992). IEEE Journal of Quantum Electronics, 28, 2619.
Judd, B. R. (1962). Physical Review, 197, 750.
Opelt, G. S. (1962). The Journal of Chemical Physics, 37, 511.
McCumber, D. E. (1964). Physical Review, 136, 954.
Bertalmío, M. (2020). In M. Bertalmío (Ed.), Vision models for high dynamic range and wide colour gamut imaging (pp. 131–155). Elsevier Ltd.
Liu, M., & Franko, M. (2016). International Journal of Thermophysics, 37, 67.
Zamrodah, Y. (2010). Encyclopedia of Analytical Chemistry, 15, 1.
Falcão, E. A., Eiras, J. A., Garcia, D., Medina, A. N., & Baesso, M. L. (2009). Cerâmica, 55, 337.
Power, J. F., & Salin, E. D. (1988). Analytical Chemistry, 60, 838.
Shen, J., Lowe, R. D., & Snook, R. D. (1992). Chemical Physics, 165, 385.
Sheldon, S. J., Knight, L. V., & Thorne, J. M. (1982). Applied Optics, 21, 1663.
Baesso, M. L., Shen, J., & Snook, R. D. (1992). Chemical Physics Letters, 197, 255.
Jacinto, C., Andrade, A. A., Catunda, T., Lima, S. M., & Baesso, M. L. (2005). Applied Physics Letters, 86, 034104.
Poma, P. Y., Kumar, K. U., Vermelho, M. V. D., Serivalsatit, K., Roberts, S. A., Kucera, C. J., Ballato, J., Jacobsohn, L. G., & Jacinto, C. (2015). Journal of Luminescence, 161, 306.
Musgraves, J. D., Hu, J., & Calvez, L. (2019). Handbook of glass. Springer Cham.
Rivera, V. A. G., & Manzani, D. (Eds.). In Technological advances in tellurite glasses: Properties, processing, and applications (pp. 41–57). Springer International Publishing.
Townsend, J. E., Poole, S. B., & Payne, D. N. (1987). Electronics Letters, 23, 329.
A. Argyros, In S. J. Eichhorn, J. W. S. Hearle, M. Jaffe & T. Kikutani (Eds.), Handbook of Textile Fibre Structure (pp. 458–484). Woodhead Publishing.
Desirena, H., Schülzgen, A., Sabet, S., Ramos-Ortiz, G., de la Rosa, E., & Peyghambarian, N. (2009). Optical Materials (Amst), 31, 784.
Clabel, J. L., Lozano, H. G., Marega, E., & Rivera, V. A. G. (2021). Journal of Non-Crystalline Solids, 553, 120520.
Cordeiro, C. M. B., Ng, A. K. L., & Ebendorff-Heidepriem, H. (2020). Scientific Reports, 10, 9678.
Cormier, L., Delbes, L., Baptiste, B., & Montouillout, V. (2021). Journal of Non-Crystalline Solids, 555.
Bechgaard, T. K., Goel, A., Youngman, R. E., Mauro, J. C., Rzoska, S. J., Bockowski, M., Jensen, L. R., & Smedskjaer, M. M. (2016). Journal of Non-Crystalline Solids, 441, 49.
Windeler, R. S. (2005). In R. D. Guenther (Ed.), Encyclopedia of modern optics (pp. 316–326). Elsevier Ltd.
Thompson, L. M., & Stebbins, J. F. (2012). Journal of Non-Crystalline Solids, 358, 1783.
Vani, P., Vinitha, G., & Manikandan, N. (2021). Physica Scripta, 96, 125804.
Saini, T. S., Kumar, A., & Sinha, R. K. (2017). Journal of Modern Optics, 64, 143.
Eevon, M. F. F. C., Halimah, M. K., Zakaria, A., Azurahanim, C. A. C., & Azlan, M. N. (2016). Results in Physics, 6, 761.
Rivera, V. A. G., Silva, O. B., Ledemi, Y., Messaddeq, Y., & Marega Jr, E.Collective plasmon-modes in gain media: Quantum emitters and plasmonic nanostructures. Springer.
Elmer, T. H. (1992). Engineering Materials, 4, 427.
Gangareddy, J., Bheemaiah, E., Gandhiraj, V., James, J. T., Jose, J. K., Naga, K. K., & Soma, V. R. (2018). Applied Physics B: Lasers and Optics, 124, 205.
Yue, Y., Tuheen, M. I., & Du, J. (2021). Borosilicate glasses. Elsevier Ltd.
Lu, X., Reiser, J. T., Parruzot, B., Deng, L., Gussev, I. M., Neuefeind, J. C., Graham, T. R., Liu, H., Ryan, J. V., Kim, S. H., Washton, N., Lang, M., Du, J., & Vienna, J. D. (2021). Journal of the American Ceramic Society, 104, 183.
Gomaa, H. M., Ali, I. S., Morsy, A. S., & Sayyed, M. I. (2020). Applied Physics A: Materials Science & Processing, 126, 384.
Algarni, H., Reben, M., & Yousef, E. (2018). Optik (Stuttgart), 156, 720.
Moreira, L., Falci, R. F., Darabian, H., Anjos, V., Bell, M. J. V., Kassab, L. R. P., Bordon, C. D. S., Doualan, J. L., Camy, P., & Moncorgé, R. (2018). Optical Materials (Amst), 79, 397.
Miedzinskia, R., Fuks-Janczareka, I., Rebenb, M., & Said, Y. E. S. (2018). Optical Materials (Amst), 7, 48.
Bajaj, R., Rao, A. S., & Prakash, G. V. (2022). Journal of Non-Crystalline Solids, 575, 121184.
Kaoua, S., Krimi, S., El Jazouli, A., Hlil, E. K., & Waal, D. D. (2007). Journal of Alloys and Compounds, 429, 276.
Petit, L. (2020). International Journal of Applied Glass Sciences, 11, 511.
Jagannathana, S. K. A., Rajaramakrishna, R., Rajashekara, K. M., Gangareddy, J., Pattar, K. V., Rao, S. V., Eraiah, B., Angadi, V. J., Kaewkhao, J. (2020). Journal of Non-Crystalline Solids, 538, 120010.
Lozano, E. M. J. G., Silva, O. B., Faria, W., de Camargo, A. S. S., Gonçalves, R. R., Manzani, D., Bruna, R. & Rivera, V. A. G. (2020). Journal of Luminescence, 228, 117538.
Chen, C. Z. Y., Chen, G., Liu, X., Xu, J., Zhou, X., Yang, T., & Yuan, C. (2018). Optical Materials (Amst), 81, 78.
Boudrioua, A. (2009). Photonic waveguides: Theory and applications. Wiley.
Rivera, V. A. G. (2012). In Inamuddin & Mohammad Luqman (Eds.), Ion exchange technology (pp. 467–490). Springer, Dordrecht.
Sgibnev, Y. M., Nikonorov, N. V., Vasilev, V. N., & Ignatiev, A. I. (2015). Journal of Lightwave Technology, 33, 3730.
Eaton, S. M., Hadden, J. P., Bharadwaj, V., Forneris, J., Picollo, F., Bosia, F., Sotillo, B., Giakoumaki, A. N., Jedrkiewicz, O., Chiappini, A., Ferrari, M., Osellame, R., Barclay, P. E., Olivero, P., & Ramponi, R. (2019). Advanced Quantum Technologies, 2, 1900006.
Poole, S. B., Payne, D. N., Mears, R. J., Fermann, M. E., & Laming, R. I. (1986). Journal of Lightwave Technology, 4, 870.
Ahmed Simon, A., Badamchi, B., Subbaraman, H., Sakaguchi, Y., Jones, L., Kunold, H., van Rooyen, I. J., & Mitkova, M. (2021). Scientific Reports, 11, 14311.
Sun, T., Xue, X., Yang, Y., Lin, C., Dai, S., Zhang, X., Ji, W., & Chen, F. (2019). Journal of Non-Crystalline Solids, 522, 119562.
Mochalov, L., Nezhdanov, A., Usanov, D., Markelov, A., Trushin, V., Chidichimo, G., De Filpo, G., Gogova, D., & Mashin, A. (2017). Superlattices and Microstructures, 111, 173.
Lin, C., Chen, D., Weng, K., Jiao, Q., Ren, J., & Dai, S. (2020). The Journal of Physical Chemistry Letters, 11, 6084.
Fedus, K., Boudebs, G., Coulombier, Q., Troles, J., & Zhang, X. H. (2010). Journal of Applied Physics, 107, 023108.
Velmuzhov, A. P., Sukhanov, M. V., Anoshina, D. E., Patrushev, D. O., Plekhovich, A. D., Evdokimov, I. I., Kurganova, A. E., & Shiryaev, V. S. (2022). Journal of Non-Crystalline Solids, 585, 121529.
Tveryanovich, Y. S., Fazletdinov, T. R., Tverjanovich, A. S., Pankin, D. V., Smirnov, E. V., Tolochko, O. V., Panov, M. S., Churbanov, M. F., Skripachev, I. V., & Shevelko, M. M. (2022). Chemistry of Materials, 34, 2743.
Jiang, X., Lousteau, J., & Jha, A. (2010). Journal of the American Ceramic Society, 93, 3259.
Cabello, F., Sanchez-Cortes, S., & Jiménez de Castro, M. (2016). Journal of Non-Crystalline Solids, 445–446, 110.
Cai, M., Zhou, B., Wang, F., Wei, T., Tian, Y., Zhou, J., Xu, S., & Zhang, J. (2015). Scientific Reports, 5, 13056.
Pierce, M. C., Jackson, S. D., Dickinson, M. R., King, T. A., & Sloan, P. (2000). Lasers in Surgery and Medicine, 26, 491.
Kassab, L. R. P., Da Silva, D. S., & De Araújo, C. B. (2010). Journal of Applied Physics, 107, 113506.
Alderman, O. L. G., Hannon, A. C., Feller, S., Beanland, R., & Holland, D. (2017). The Journal of Physical Chemistry C, 121, 9462.
Murthy, M. K. (1964). Nature, 201, 285.
Jiang, X., Lousteau, J., Richards, B., & Jha, A. (2009). Optical Materials (Amst), 31, 1701.
Wei, T., Tian, Y., Chen, F., Cai, M., Zhang, J., Jing, X., Wang, F., Zhang, Q., & Xu, S. (2014). Scientific Reports, 4, 6060.
Hunt, D. L., Lai, C., Smith, R. D., Lee, A. K., Harris, T. D., & Barbic, M. (2019). Nature Biomedical Engineering, 3, 741.
Cheng, H. S. P., Zhou, Y., Su, X., Zhou, M., & Zhou, Z. (2018). Journal of Luminescence, 197, 31.
Roca, P. A. N., & Garcia-Valles, M. (2021). Materials Letters, 305, 130741.
Li, J. M. Z., Huang, Z., Sun, F., & Li, X. (2020). Mater. Today Adv., 7, 100077.
Chen, M. (2011). NPG Asia Materials, 3, 82.
Liu, N., Ma, T., Liao, C., Liu, G., Mota, R. M. O., Liu, J., Sohn, S., Kube, S., Zhao, S., Singer, J. P., & Schroers, J. (2021). Scientific Reports, 11, 1.
Han, Y., Wang, L., Liu, K., & Yan, W. (2020). Journal of Micromechanics and Molecular Physics, 5, 2050013.
Mao, L. Y., Liu, J. L., Li, L. X., & Wang, W. C. (2020). Journal of Non-Crystalline Solids, 531, 119855.
Nong, X. D., Zhou, X. L., & Ren, Y. X. (2019). Optics & Laser Technology, 109, 20.
Zhang, P., Tan, J., Tian, Y., Yan, H., & Yu, Z. (2022). The International Journal of Advanced Manufacturing Technology, 118, 2017.
Moore, D. G., Barbera, L., Masania, K., & Studart, A. R. (2020). Nature Materials, 19, 212.
Khmyrov, R. S., Protasov, C. E., Grigoriev, S. N., & Gusarov, A. V. (2016). The International Journal of Advanced Manufacturing Technology, 85, 1461.
Rodrigo-Vázquez, I. H. C. S., Kamboj, N., Aghayan, M., Sáez, A., De Aza, A. H., Rodríguez, M. A. (2020). Ceramics International, 46, 26936.
Pan, Z., Morgan, S. H., & Long, B. H. (1995). Journal of Non-Crystalline Solids, 185, 127.
Mori, A., Masuda, H., Shikano, K., & Shimizu, M. (2003). Journal of Lightwave Technology, 21, 1300.
Chu, Y., Ren, J., Zhang, J., Peng, G., Yang, J., Wang, P., & Yuan, L. (2016). Scientific Reports, 6, 33865.
Yablonovitch, Eli. (1987). IET Conference Publication, 58, 2059.
John, S. (1987). Physical Review Letters, 58, 2486.
Dawes, J. M. (2020). Synthesis, characterization, and applications of opals. Elsevier Inc.
Russell, P. S. J. (2006). Journal of Lightwave Technology, 24, 4729.
Nagel, S. R., MacChesney, J. B., & Walker, K. L. (1982). IEEE Transactions on Microwave Theory and Techniques, 30, 305.
Wang, Y., Jiang, G., Yu, Z., Wang, Q., & Jiang, X. (2021). Results in Optics, 5, 100137.
Kotz, F., Risch, P., Arnold, K., Sevim, S., Puigmartí-Luis, J., Quick, A., Thiel, M., Hrynevich, A., Dalton, P. D., Helmer, D., & Rapp, B. E. (2019). Nature Communications, 10, 1439.
Hu, D. J. J., Xu, Z., & Shum, P. P. (2019). IEEE Access, 7, 67469.
Von Witzendorff, P., Pohl, L., Suttmann, O., Heinrich, P., Heinrich, A., Heinrich, A., Zander, J., & Bragard, H. (2018). Procedia CIRP, 74, 272.
Ward, J. M., Yang, Y., & Chormaic, S. N. (2016). Scientific Reports, 6, 25152.
Zindani, K. K. D. (2019). International Journal of Lightweight Materials and Manufacture, 2, 267.
Righini, G. C., & Soria, S. (2016). Sensors (Switzerland), 16, 1.
Manzani, D., Gualberto, T., Almeida, J. M. P., Montesso, M., Mendonça, C. R., Rivera, V. A. G., De Boni, L., Nalin, M., & Ribeiro, S. J. L. (2016). Journal of Non-Crystalline Solids, 443, 82.
Miedzinski, R., Fuks-Janczarek, I., Kassab, L. R. P., & Bomfim, F. A. (2017). Materials Research Bulletin, 95, 339.
Santos, F. A., Figueiredo, M. S., Barbano, E. C., Misoguti, L., Lima, S. M., Andrade, L. H. C., Yukimitu, K., & Moraes, J. C. S. (2017). Ceramics International, 43, 15201.
Misoguti, L., Kassab, L. R., Bordon, C. D., Rodrigues Jr, J. J., & Alencar, M. A. (2021). Journal of Alloys and Compounds, 872, 159738.
Jagannath, G., Eraiah, B., Krishnakanth, K. N., & Rao, S. V. (2018). Journal of Non-Crystalline Solids, 482, 160.
Santos, S. N. C., Almeida, J. M. P., Paula, K. T., Tomazio, N. B., Mastelaro, V. R., & Mendonça, C. R. (2017). Optical Materials (Amst), 73, 16.
Jagannath, G., Eraiah, B., Gaddam, A., Fernandes, H., Brazete, D., Jayanthi, K., Krishnakanth, K. N., Rao, S. V., Ferreira, J. M. F., Annapurna, K., & Allu, A. R. (2019). The Journal of Physical Chemistry C, 123, 5591.
Zhao, J., Zhao, Y., Peng, Y., Lv, R. Q., & Zhao, Q. (2022).Optics & Laser Technology, 146, 107473.
Silva, D. S., Wetter, N. U., Rossi, W., Kassab, L. R. P., & Samad, R. E. (2018). Optical Materials (Amst), 75, 267.
Oliveira, J. M., Jesus-Silva, A. J., Silva, A. C. A., Dantas, N. O., & Fonseca, E. J. S. (2020). Optical Materials (Amst), 101, 109767.
Selvaraja, S. K., & Sethi, P. (2018). In K. Y. You (Ed.), Emerging waveguide technology (pp. 95–129). IntechOpen.
Paschotta, R. (2010). Field guide to optical fiber technology. SPIE Press.
Agrawal, G. P. (2005). Lightwave technology: Telecommunication systems. Wiley-Interscience.
Alazoumi, S. H., Aziz, S. A., El-Mallawany, R., Aliyu, U. S. A., Kamari, H. M., Zaid, M. H. M. M., & Matori, K. A. (2018). Results in Physics, 9, 1371.
Motorin, S. E., Dorofeev, V. V., Galagan, B. I., Sverchkov, S. E., Koltashev, V. V., & Denker, B. I. (2018). IOP Conference Series: Materials Science and Engineering, 347, 012038.
Dan, H. K., Ty, N. M., Nga, V. H., Phuc, D. T., Phan, A. L., Zhou, D., & Qiu, J. (2020). Journal of Non-Crystalline Solids, 549, 120335.
Rivera, V. A. G., Ledemi, Y., El-Amraoui, M., Messaddeq, Y., & Marega, E. (2014). Optics Express, 22, 21122.
Mori, A., Ohishi, Y., Yamada, M., Ono, H., & Sudo, S. (1997). Integrated Optics and Optical Fibre Communications, 11th International Conference (pp. 135–138).
Chillcce, E. F., Rodriguez, E., Neves, A. A. R., Moreira, W. C., César, C. L., & Barbosa, L. C. (2006). Optical Fiber Technology, 12, 185.
Tang, Z., Shiryaev, V. S., Furniss, D., Sojka, L., Sujecki, S., Benson, T. M., Seddon, A. B., & Churbanov, M. F. (2015). Optical Materials Express, 5, 1722.
Wang, N., Cao, R., Cai, M., Shen, L., Tian, Y., Huang, F., Xu, S., & Zhang, J. (2017). Optics & Laser Technology, 97, 364.
Zhou, M., Zhou, Y., Su, X., Zhu, Y., Zhou, Z., & Cheng, P. (2018). Journal of Non-Crystalline Solids, 481, 344.
Liu, Z., Gan, H., Xia, K., Gui, Y., Zhang, X., Zeng, N., Cao, Z., Wang, X., & Dai, S. (2021). Journal of Alloys and Compounds, 865, 158170.
Chen, M., Li, W., Ji, S., Lin, X., Zhan, X., Xu, H., & Cai, Z. (2019). Optical Materials (Amst), 97, 109351.
Campbell, J. H., Hayden, J. S., & Marker, A. (2011). International Journal of Applied Glass Science, 2, 3.
Kenyon, A. J. (2002). Progress in Quantum Electronics, 26, 225.
Codemard, C., Zervas, M. N., & Codemard, C. A. (2014). IEEE Journal of Selected Topics in Quantum Electronics, 20, 0904123.
Silfvast, W. T., & Tjossem, P. J. H. (1997). American Journal of Physics, 65, 932.
Liu, L., Xing, J., Shang, F., & Chen, G. (2021). Optics Communications, 490, 126944.
Dianov, E. M. (2002). Journal of Lightwave Technology, 20, 1457.
Rifat, A. A., Haider, F., Ahmed, R., Mahdiraji, G. A., Adikan, F. M., & Miroshnichenko, A. E. (2018). Optics Letters, 43, 891.
Soler-Carracedo, K., Ruiz, A., Martín, I. R., & Lahoz, F. (2019). Journal of Alloys and Compounds, 777, 198.
Venkatakrishnarao, D., Sahoo, C., Mamonov, E. A., Novikov, V. B., Mitetelo, N. V., Naraharisetty, S. R. G., Murzina, T. V., & Chandrasekar, R. (2017). Journal of Materials Chemistry C, 5, 12349.
Schliesser, A., Picqué, N., & Hänsch, T. W. (2012). Nature Photonics, 6, 440.
Ramesh, P., Hegde, V., Pramod, A. G., Eraiah, B., Rao, S. V., Shisina, S., Das, S., Agarkov, D. A., Eliseeva, G. M., Jagannath, G., & Kokila, M. K. (2020). Optical Materials (Amst), 108, 110051.
Rivera, V. A. G., Ferri, F. A., Nunes, L. A. O., & Marega, E. (2017). Optical Materials (Amst), 67, 25.
Camilo, M. E., Silva, E. D. O., Kassab, L. R. P., Garcia, J. A. M., & De Araújo, C. B. (2015). Journal of Alloys and Compounds, 644, 155.
Macrelli, G., Varshneya, A. K., & Mauro, J. C. (2020). Optical Materials (Amst), 106, 109994.
Righini, G. C., Szczurek, A., Krzak, J., Lukowiak, A., Ferrari, M., Varas, S., & Chiasera, A. (2020). International conference on transparent optical networks 2020 (p. 3).
Ma, H., Jen, A. K. Y., & Dalton, L. R. (2002). Advanced Materials, 14, 1339.
Kim, S., Van Quy, H., & Bark, C. W. (2021). Materials Today Energy, 19, 100583.
Li, X., Li, P., Wu, Z., Luo, D., Yu, H.-Y., & Lu, Z.-H. (2021). Materials Reports, 1, 100001.
Acknowledgements
The authors acknowledge financial support from the Brazilian Institutions: São Paulo Research Foundation (FAPESP) under the grant 2013/07276-1, 2020/04835-3, and 2021/11484-5. Besides the Canadian Excellence Research Chair program (CERC) in Photonics Innovations, the Discovery Grant program of the Natural Sciences and Engineering Research Council of Canada (NSERC), the Fonds de Recherche Québecois sur la Nature et les Technologies (FRQNT), and the Canadian Foundation for Innovation (CFI).
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2023 The Author(s), under exclusive license to Springer Nature Switzerland AG
About this chapter
Cite this chapter
Clabel H., J.L. et al. (2023). Overall Aspects of Glasses for Photonic Devices. In: Ikhmayies, S.J. (eds) Advances in Glass Research. Advances in Material Research and Technology. Springer, Cham. https://doi.org/10.1007/978-3-031-20266-7_1
Download citation
DOI: https://doi.org/10.1007/978-3-031-20266-7_1
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-031-20265-0
Online ISBN: 978-3-031-20266-7
eBook Packages: Chemistry and Materials ScienceChemistry and Material Science (R0)