Planar Bulk MOSFETs With Self-Aligned Pocket Well to Improve Short-Channel Effects and Enhance Device Performance

Zhang, Yanbo; Zhu, Huilong; Wu, Hao; Zhang, Yongkui; Zhao, Zhiguo; Zhong, Jiahao; Yang, Hong; Liang, Qi; Wang, Dahai; Li, Junfeng; Cheng, Junyi; Liu, Jinbiao; Zhao, Yannan; Li, Chunlong; Meng, Lingkuan; Hong, Peizhen; Li, Junjie; Xu, Qing; Gao, Jianfeng; He, Xiaobin; Lu, Yihong; Zhang, Yue; Yang, Yongzhen; Wang, Yao; Cui, Hushan; Zhao, Chao; Zhong, Huicai; Yin, Haizhou; Jiang, Yan; Wang, Wenwu; Chen, Dapeng; Yu, Hongyu; Yang, Sen; Ye, Tianchun

doi:10.1109/ted.2015.2410799

Cited by 13 publications

(6 citation statements)

References 10 publications

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“…This could generate a GC device without any implantation requirement of lightly doped region by chemical doping. The use of GC by chemical doping to improve the device performance has been a proven technique [24][25][26]. The improvement in device performance is measured in terms of I ON /I OFF ratio, sub-threshold slope (SS), drain-induced barrier lowering (DIBL), and cut-off frequency 'f T ' as shown in Figs.…”

Section: Graded Channel (Gc) Edd-jamfetmentioning

confidence: 99%

Design approach to improve the performance of JAMFETs

Raushan

Alam

Siddiqui

2020

IET Circuits, Devices & Systems

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In this paper, the authors propose the use of electrostatic doping for n + drain region formation in Junctionless accumulation mode field effect transistors (JAMFET). This electrostatically doped drain (EDD) JAMFET employs an additional unbiased electrode (auxiliary electrode) of low workfunction on the intrinsic drain region. This technique effectively suppresses the tunneling leakage, thereby reducing I OFF by 6 orders. The tunneling of electrons from valence band of channel to conduction band of drain happens due to enhanced band bending in OFF-state (V GS = 0 V, V DS = 1 V). The presence of additional electrode in EDD-JAMFET increases the width of tunnel barrier formed at channel-drain junction in OFF-state improving the I ON /I OFF ratio by 6 orders. The gate length scaling demonstrates that leakage suppression of EDD-JAMFET is more effective with approximately 3 orders smaller I OFF even at gate length of 5 nm. The performance of graded channel device (GC-EDD-JAMFET) by electrostatic doping is also explored. Significant improvements are observed in terms of I ON /I OFF , subthreshold slope SS, DIBL and f T. Finally, the analogue parameters such as Transconductance generation factor G m /I D , Intrinsic gain A V , output conductance G D , and 'G m /I D × f T ' performance metrics are investigated which show significant improvement at small bias current, making it suitable for ultra-low power applications.

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Section: Graded Channel (Gc) Edd-jamfetmentioning

confidence: 99%

Design approach to improve the performance of JAMFETs

Raushan

Alam

Siddiqui

2020

IET Circuits, Devices & Systems

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“…21 The pocket layer insertion has been employed in conventional MOS devices to improve the SCEs significantly. 24,25 On the other hand, the introduction of pocket layer in the source or channel of a TFET leads to suppression of SCEs, reduction of SS, lower I OFF , and higher I ON, 21,22,[26][27][28][29] However, it is important to mention that controlled fabrication is one of the major issues in such pocket-based structures. In 2014, the experimental fabrication of a line TFET with 6 to 7-nm silicon pocket has been reported by Walke et al 16 In 2005, Jahan et al demonstrated the experimental feasibility of growing an ultrathin silicon layer up to 3.4 nm using the selective epitaxial growth process.…”

Section: Introductionmentioning

confidence: 99%

“…Kao et al, in 2012, proposed a solution to counter these limitations in gate on source configurations by introducing a pocket layer beneath the source 21 . The pocket layer insertion has been employed in conventional MOS devices to improve the SCEs significantly 24,25 . On the other hand, the introduction of pocket layer in the source or channel of a TFET leads to suppression of SCEs, reduction of SS, lower I OFF , and higher I ON, 21,22,26‐29 However, it is important to mention that controlled fabrication is one of the major issues in such pocket‐based structures.…”

Section: Introductionmentioning

confidence: 99%

Z‐shaped gate TFET with horizontal pocket for improvement of electrostatic behavior

Sahoo

Dash

Routray

et al. 2020

Int J Numerical Modelling

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In this paper, a new Z-shaped gate TFET structure is proposed with an n+ horizontal pocket insertion beneath the source. The Z-TFET structure provides higher ON current by 2-decades as compared to conventional TFET due to the vertical tunneling and presence of HfO 2 gate oxide. Similarly, the ambipolar current reduces by 2-decades without affecting subthreshold swing (SS) and OFF current significantly. The ON current is further improved by positioning

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“…Silicon-based nanostructures including Si and SiO 2 are of great technological importance and considerable interest, and they have been extensively exploited for a wide variety of scientific and engineering applications ranging from attractive plasmonic [1, 2], sensitive biosensor devices [3, 4], phonics crystals to magnetic storage media [5, 6] and are also the building blocks for a broad range of nanoelectronic devices such as MOSFET [7, 8], nanofluidics [9, 10], and optoelectronics devices [11, 12]. Accordingly, there have been a large number of fabrication techniques and methods to produce highly controlled silicon-based nanostructures using top-down or bottom-up patterning strategies in the literatures [13–15].…”

Section: Introductionmentioning

confidence: 99%

A Novel Nanofabrication Technique of Silicon-Based Nanostructures

Meng

Gao

et al. 2016

Nanoscale Res Lett

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A novel nanofabrication technique which can produce highly controlled silicon-based nanostructures in wafer scale has been proposed using a simple amorphous silicon (α-Si) material as an etch mask. SiO2 nanostructures directly fabricated can serve as nanotemplates to transfer into the underlying substrates such as silicon, germanium, transistor gate, or other dielectric materials to form electrically functional nanostructures and devices. In this paper, two typical silicon-based nanostructures such as nanoline and nanofin have been successfully fabricated by this technique, demonstrating excellent etch performance. In addition, silicon nanostructures fabricated above can be further trimmed to less than 10 nm by combing with assisted post-treatment methods. The novel nanofabrication technique will be expected a new emerging technology with low process complexity and good compatibility with existing silicon integrated circuit and is an important step towards the easy fabrication of a wide variety of nanoelectronics, biosensors, and optoelectronic devices.

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Planar Bulk MOSFETs With Self-Aligned Pocket Well to Improve Short-Channel Effects and Enhance Device Performance

Cited by 13 publications

References 10 publications

Design approach to improve the performance of JAMFETs

Design approach to improve the performance of JAMFETs

Z‐shaped gate TFET with horizontal pocket for improvement of electrostatic behavior

A Novel Nanofabrication Technique of Silicon-Based Nanostructures

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