Critical technology challenges in low power electronics

Proceedings of SEMI Advanced Semiconductor Manufacturing Conference and Workshop Pub Date : 1995-11-13 DOI:10.1109/ASMC.1995.484357

R. Singh, R. Sharangpani, K. F. Poole, M. Moslehi

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引用次数: 4

Abstract

The availability of ULSI CMOS operating at 1 V can lead to several revolutionary applications. In addition to innovative circuit designs, new materials and processes need to be developed for low power electronics. This is due to the fact that power dissipation depends on parasitic capacitance. Critical technologies are high quality high and low K dielectric materials and appropriate metalization schemes. We have successfully used rapid isothermal processing (RIP) for the deposition of high K and low K dielectric materials. We have used RIP assisted metalorganic chemical vapor deposition (MOCVD) technique for the deposition of high K materials having very low leakage current density (<1 pA/cm/sup 2/ at 1 V). It has been found that even at low processing temperatures (300 to 400/spl deg/C) the residual stress of the materials processed by conventional furnaces is much higher than that can be obtained by RIP. From the manufacturing point of view, new equipments need to be developed for the successful implementation of new technologies. The objective of this paper is to present our recent materials and processing results and the possible directions in meeting the equipment and process integration challenges.

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低功耗电子的关键技术挑战

工作在1v的ULSI CMOS的可用性可以导致几个革命性的应用。除了创新的电路设计外，还需要为低功耗电子产品开发新的材料和工艺。这是因为功率耗散取决于寄生电容。关键技术是高质量的高、低K介电材料和合适的金属化方案。我们已经成功地使用快速等温处理(RIP)沉积高K和低K介电材料。我们使用RIP辅助金属有机化学气相沉积(MOCVD)技术沉积了泄漏电流密度非常低(<1 pA/cm/sup 2/ at 1 V)的高K材料。研究发现，即使在较低的加工温度(300至400/spl℃)下，传统炉加工的材料的残余应力也远高于RIP。从制造的角度来看，新技术的成功实施需要开发新设备。本文的目的是介绍我们最近的材料和加工成果以及可能的方向，以满足设备和工艺集成的挑战。

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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Proceedings of SEMI Advanced Semiconductor Manufacturing Conference and Workshop

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