Sub-5nm All-Around Gate FinFET for Ultimate Scaling

Lee, H.; Yu, L.-E.; Ryu, Seong-Wan; Han, Joon‐Kyu; Jeon, Kun-Rok; Jang, Doojin; Kim, Kyeong-Hwa; Lee, J.; Kim, J.-H.; Jeon, Seol-Hee; Lee, G.; Oh, Jin Kyung; Park, Y.; Bae, Woo-Ho; Lee, H.; Yang, J.; Yoo, Jaehyun; Kim, S.; Choi, Yang‐Kyu

doi:10.1109/vlsit.2006.1705215

Cited by 95 publications

(60 citation statements)

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“…The best electrostatic control can be achieved with a cylindrical channel surrounded by the gate. This has already been shown in a sub-5-nm gate length nanowire-FET [47,49].…”

Section: Multigate Devicessupporting

confidence: 62%

Ultra-thin films and multigate devices architectures for future CMOS scaling

Deleonibus

2011

Sci. China Inf. Sci.

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The nanoelectronics industry is facing historical challenges to scale down CMOS devices to meet demands for low voltage, low power, high performance and increased functionality. Using new materials and devices architectures is necessary. HiK gate dielectrics and metal gates have been introduced and have shown their ability to reduce power consumption. Fully depleted ultra-thin SOI devices are a good alternative to bulk for low power applications. Multigate devices are the current goal in device architecture to increase MOSFET drivability, reduce power, and allow new opportunities for future applications. Thin film based solutions will be necessary in the future because of fundamental limitations on gate capacitance scaling and system integration requirements. Exploiting 3D device stacking via wafer bonding could be a good way to introduce new materials (HiK, strained Si, hybrid orientations, Ge, III-Vs, Carbon-based materials, graphene and CNTs, and functional molecules) and continue increasing integration density. Si based CMOS will be scaled beyond the ITRS as the System-on-Chip/Wafer Platform.The international technology roadmap of semiconductors (ITRS) [1] distinguishes three types of products: high performance (HP), low operating power (LOP) and low standby power (LSTP) devices. In the HP case, a landmark has been reached at the 32-nm node: the contribution from static power dissipation approaches the dynamic power contribution [2]. Multigate devices could improve this somewhat by increasing the saturation current to leakage current ratio.In this review, we will first analyze the primary limitations and showstoppers of CMOS scaling. Issues on gate stack, channel and source and drain engineering as well as new device architectures (FDSOI or multigate devices) are discussed.Low power consumption and heterogeneous function integration will be leveraged by future nomadic systems. The increased number of devices and different types of signals will, in turn, require the leveraging of 3D IN package or ON chip co-integration. Limitations, showstoppers and opportunities of Si CMOS scalingCMOS device engineering consists of minimizing leakage current and the maximization of output current. In sub-100-nm CMOS devices, non-stationary transport is more important than diffusive transport. To this end, several questions arise related to the origins of the leakage currents, non-stationary transport limitations and supply voltage scaling.

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“…The best electrostatic control can be achieved with a cylindrical channel surrounded by the gate. This has already been shown in a sub-5-nm gate length nanowire-FET [47,49].…”

Section: Multigate Devicessupporting

confidence: 62%

Ultra-thin films and multigate devices architectures for future CMOS scaling

Deleonibus

2011

Sci. China Inf. Sci.

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show abstract

“…Similar trends of V T shift have also been observed in Si FinFETs as well as InGaAs nanowire transistors. This narrow channel effect was ascribed to the lateral expansion of depletion layer due to fringing field effect or quantum confinement in device channels [19][20][21]. However, the channel widths are strickly defined in our MoS 2 transistors thus they cannot have a lateral expansion in depletion layer.…”

Section: Methodsmentioning

confidence: 88%

$\hbox{MoS}_{2}$ Nanoribbon Transistors: Transition From Depletion Mode to Enhancement Mode by Channel-Width Trimming

Liu

2012

IEEE Electron Device Lett.

107

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“…An n-channel FinFET with a channel length of 30 nm and a channel width of 20 nm was first demonstrated in 1998 [9]. The smallest FinFET was reported in 2006, which had a channel length of 5 nm and a channel width of 3 nm [10]. In 2011, a leader in the semiconductor industry officially announced that it would use FinFETs in mass production at the 22 nm generation of CMOS technology [11,12].…”

Section: Thin Body Mosfets Allow Cmos Technology To Move Forward Aggrmentioning

confidence: 99%

Introduction: Barriers Preventing CMOS Device Technology from Moving Forward

Shin

2016

Variation-Aware Advanced CMOS Devices and SRAM

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Sub-5nm All-Around Gate FinFET for Ultimate Scaling

Cited by 95 publications

References 1 publication

Ultra-thin films and multigate devices architectures for future CMOS scaling

Ultra-thin films and multigate devices architectures for future CMOS scaling

$\hbox{MoS}_{2}$ Nanoribbon Transistors: Transition From Depletion Mode to Enhancement Mode by Channel-Width Trimming

Introduction: Barriers Preventing CMOS Device Technology from Moving Forward

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