Thin metal oxide films for application in nanoscale devices

27th International Spring Seminar on Electronics Technology: Meeting the Challenges of Electronics Technology Progress, 2004. Pub Date : 2004-05-13 DOI:10.1109/ISSE.2004.1490429

P. Vitanov, A. Harizanova, T. Ivanova

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引用次数: 2

Abstract

To scale MOS transistors beyond 100 nm, it is imperative to find a dielectric of high permittivity (high-k dielectric) to replace the current SiO/sub 2/ as a gate insulator. In principle, a high dielectric can deliver an equivalent SiO/sub 2/ thickness of 1 nm with a greater physical thickness (20 nm if k=80) and, hence lower leakage current. Realizing the promise of high-k dielectrics in the ULSI technology is an enormously challenging task. There are several classes of dielectric, such as oxides and fluorides. The simplest such oxides have one metallic element, e.g. HfO/sub 2/, ZrO/sub 2/, Y/sub 2/O/sub 3/ with rare earth metals. Their dielectric constant range is from 10-30. More complex such oxides have two different metallic elements such as BaTiO/sub 3/ and SrTiO/sub 3/. They can form solid-state solutions with each other at all ratios, because of their identical crystal structures. That is why thin films of barium titanate (BTO) and barium strontium titanate (BSTO) of a permittivity in the range of 100-400 and greater specific capacitance, have emerged as a leading contender as a gate dielectric for sub - 0.1 mm MOS transistors. In this study results are reported of the structural and dielectric properties of several thin films prepared by the sol-gel method. The electrical properties are investigated on MIS structures and the results are related to the effect of reaction with the silicon substrate upon thermal annealing.

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纳米级器件中应用的金属氧化物薄膜

为了使MOS晶体管的尺寸超过100 nm，必须找到一种高介电常数的介电介质(高k介电介质)来取代目前的SiO/sub 2/作为栅极绝缘体。原则上，高介电介质可以提供1 nm的等效SiO/sub /厚度，具有更大的物理厚度(如果k=80则为20 nm)，因此泄漏电流更小。在ULSI技术中实现高k介电体的承诺是一项极具挑战性的任务。电介质有好几类，如氧化物和氟化物。最简单的这种氧化物只有一种金属元素，如HfO/sub 2/、ZrO/sub 2/、Y/sub 2/O/sub 3/与稀土金属。介电常数范围为10-30。更复杂的氧化物有两种不同的金属元素，如btio / sub3 /和SrTiO/ sub3 /。由于它们的晶体结构相同，它们可以以任何比例相互形成固态溶液。这就是为什么钛酸钡(BTO)和钛酸钡锶(BSTO)薄膜的介电常数范围在100-400和更高的比电容范围内，已经成为亚0.1 mm MOS晶体管栅极介电介质的主要竞争者。本文报道了溶胶-凝胶法制备的几种薄膜的结构和介电性能。研究了MIS结构的电学性能，其结果与与硅衬底的反应对热退火的影响有关。

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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27th International Spring Seminar on Electronics Technology: Meeting the Challenges of Electronics Technology Progress, 2004.

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