Device Design Consideration for Nanoscale MOSFET Using Semiconductor TCAD Tools

T. C. Hong, R. Ismail
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引用次数: 8

Abstract

The evolution of metal-oxide-semiconductor field effect transistor (MOSFET) technology has been governed mainly by device scaling over the past twenty years. One of the key questions concerning future ULSI technology is whether MOSFET devices can be scaled to 100 nmchannel length and beyond for continuing density and performance improvement. In this paper, the design, fabrication and characterization of high-performance and low-power 90 nm channel length MOSFET devices are described. Several parameters have to be scaled down such as gate oxide thickness, channel length, ion implantation for threshold voltage adjustment and other specifications to achieve desirable electrical characteristic. To control the short-channel effect (SCE) and hot-carrier reliability that limits device scaling, lightly doped drain (LDD) structure, shallow junction of drain / source and Shallow Trench Isolation (STI) are implemented. Virtual wafer fabrication (VWF) Silvaco TCAD Tools is used for fabrication and simulation of CMOS transistor namely ATHENA and ATLAS. Simulations using these programs provided the opportunity to study the effect of different device parameters on the overall device performance. The devices were simulated and gradually the performance of each one was improved, until an optimal device configuration was created for a particular application.
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利用半导体TCAD工具设计纳米级MOSFET器件的考虑
在过去的二十年中,金属氧化物半导体场效应晶体管(MOSFET)技术的发展主要受器件缩放的影响。未来ULSI技术的关键问题之一是MOSFET器件是否可以扩展到100纳米通道长度,以持续提高密度和性能。本文介绍了高性能、低功耗90 nm沟道长度MOSFET器件的设计、制造和特性。几个参数必须按比例缩小,如栅极氧化物厚度,通道长度,离子注入阈值电压调整和其他规格,以达到理想的电气特性。为了控制限制器件扩展的短通道效应(SCE)和热载流子可靠性,实现了轻掺杂漏极(LDD)结构、漏极/源极浅结和浅沟槽隔离(STI)。虚拟晶圆制造(VWF) Silvaco TCAD工具用于制造和模拟CMOS晶体管即ATHENA和ATLAS。使用这些程序的模拟提供了研究不同器件参数对整体器件性能的影响的机会。对这些设备进行了模拟,并逐渐提高了每个设备的性能,直到为特定应用程序创建了最佳设备配置。
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