Sol-gel materials for opto(electronic) applications

Polytronic 2005 - 5th International Conference on Polymers and Adhesives in Microelectronics and Photonics Pub Date : 2005-10-23 DOI:10.1109/POLYTR.2005.1596509

K. Maruszewski

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引用次数: 1

Abstract

Conventional glass preparation requires melting of precursors at high temperatures, rapid cooling and subsequent vitrification of the glassy material. This procedure highly restricts choice of substances which can be entrapped in the glass products. Basically only metal oxides and some inorganic salts can survive such drastic conditions avoiding thermal decomposition. Furthermore, the way in which conventional glass is produced makes thin films preparation extremely cumbersome and the only method of preparation of porous classical glasses requires etching or partial dissolving (e.g. Vycor® glass). On the other hand glass and glassy materials possess several useful features for e.g. optical applications such as transparency, homogeneity, mechanical sturdiness, high refractive index etc. An alternative approach to glass and glass-like materials production is offered by the sol-gel technology. The process itself is known for more than a century, but it has gained a new importance in the last two decades after pioneering results of Dislich. He and other researchers improved the chemistry of the process so much that it is now possible to obtain samples in days (or even hours — in case of thin films) rather than months (or years) like in the case of the early samples. The sol-gel technique is based on hydrolysis of liquid precursors and formation of colloidal sols. The precursors are usually organosilicates (e.g. TEOS — tetraethoxysilane) giving silicate sol-gel materials. However, the method is not restricted to the silica compounds — for example precursors based on Ti, Zr, V etc.

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光电应用的溶胶-凝胶材料

传统的玻璃制备需要在高温下熔化前驱体，快速冷却并随后玻璃化材料的玻璃化。这一程序严格限制了玻璃制品中可能夹带的物质的选择。基本上，只有金属氧化物和一些无机盐能在如此极端的条件下生存，避免热分解。此外，传统玻璃的生产方式使得薄膜制备非常繁琐，制备多孔经典玻璃的唯一方法需要蚀刻或部分溶解(例如Vycor®玻璃)。另一方面，玻璃和玻璃材料具有一些有用的特性，例如光学应用，如透明度，均匀性，机械坚固性，高折射率等。溶胶-凝胶技术为玻璃和类玻璃材料的生产提供了另一种方法。这个过程本身已经有一个多世纪的历史了，但在过去的二十年里，在迪利希的开创性成果之后，它获得了新的重要性。他和其他研究人员极大地改进了这一过程的化学性质，现在可以在几天(甚至几小时——如果是薄膜)内获得样品，而不是像早期的样品那样几个月(或几年)。溶胶-凝胶技术是基于液体前体的水解和胶体溶胶的形成。前驱体通常是有机硅酸盐(如TEOS -四乙氧基硅烷)，形成硅酸盐溶胶-凝胶材料。然而，该方法并不局限于二氧化硅化合物-例如基于Ti, Zr, V等的前驱体。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Polytronic 2005 - 5th International Conference on Polymers and Adhesives in Microelectronics and Photonics

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