A novel CMOS compatible L-shaped impact-ionization MOS (LI-MOS) transistor

IEEE InternationalElectron Devices Meeting, 2005. IEDM Technical Digest. Pub Date : 2005-12-05 DOI:10.1109/IEDM.2005.1609518

E. Toh, G. Wang, G. Lo, N. Balasubramanian, C. Tung, F. Benistant, L. Chan, G. Samudra, Y. Yeo

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引用次数: 23

Abstract

This paper reports a novel L-shaped impact-ionization MOS (LI-MOS) transistor technology that achieves subthreshold swing well below 60 mV/decade at room temperature. First, the LI-MOS transistor is CMOS process compatible, and requires little process modification for integration in a manufacturable process. Second, the LI-MOS structure employs raised source/drain (S/D) regions that enable controllability and scalability of the impact ionization region (I-region). Third, the LI-MOS has superior compactness over previously reported I-MOS device structures. Fourth, the LI-MOS enables the integration of novel materials for band gap and strain engineering to enhance the impact ionization rate in the I-region. Based on the above technology, we demonstrate a record subthreshold swing of 4.5 mV/decade at room temperature for a 100 run gate length device that incorporates a SiGe I-region. The smallest impact-ionization-based MOS device with a gate length of 60 nm is also demonstrated with a subthreshold swing that is well below 60 mV/decade

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一种新型兼容CMOS的l形冲击电离MOS晶体管

本文报道了一种新型的l形冲击电离MOS (LI-MOS)晶体管技术，该技术在室温下实现了远低于60 mV/ 10年的亚阈值摆幅。首先，LI-MOS晶体管与CMOS工艺兼容，在可制造工艺中集成所需的工艺修改很少。其次，LI-MOS结构采用了凸起的源/漏(S/D)区域，使冲击电离区域(i区)具有可控性和可扩展性。第三，LI-MOS具有优于先前报道的I-MOS器件结构的紧凑性。第四，LI-MOS能够集成用于带隙和应变工程的新型材料，以提高i区冲击电离率。基于上述技术，我们展示了一个包含SiGe i区域的100栅极长度器件在室温下创纪录的4.5 mV/ 10年亚阈值摆幅。最小的基于冲击电离的MOS器件，栅极长度为60 nm，亚阈值摆幅远低于60 mV/ 10年

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IEEE InternationalElectron Devices Meeting, 2005. IEDM Technical Digest.

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