Device Design Guideline of 5-nm-Node FinFETs and Nanosheet FETs for Analog/RF Applications

Yoon, Jun-Sik; Baek, Rock‐Hyun

doi:10.1109/access.2020.3031870

Cited by 31 publications

(19 citation statements)

References 30 publications

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“…It was found that mechanical deformation could be reduced when TNS is thick, because of increased D. In the case of an n-type NS FET, a few nanometers of inner spacer is deposited between the nanosheets. Currently, most reports related with inner spacer have been performed in terms of electrical performance [20][21][22][23][24]. However, in view of the mechanical stress, the inner spacer plays a large role in the support of each nanosheet.…”

Section: Resultsmentioning

confidence: 99%

Inner Spacer Engineering to Improve Mechanical Stability in Channel-Release Process of Nanosheet FETs

Lee

Park

2021

Electronics

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Mechanical stress is demonstrated in the fabrication process of nanosheet FETs. In particular, unwanted mechanical instability stemming from gravity during channel-release is covered in detail by aid of 3-D simulations. The simulation results show the physical weakness of suspended nanosheets and the impact of nanosheet thickness. Inner spacer engineering based on geometry and elastic property are suggested for better mechanical stability. The formation of wide contact area between inner spacer and nanosheet, as well as applying rigid spacer dielectric material, are preferred.

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Section: Resultsmentioning

confidence: 99%

Inner Spacer Engineering to Improve Mechanical Stability in Channel-Release Process of Nanosheet FETs

Lee

Park

2021

Electronics

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“…where Cgg is gate capacitance, Vdd is operation voltage fixed to 0.7 V, Ion is on-state current, Ft is cut-off frequency, and Gm is transconductance. Here Ft is simply calculated as Gm/(2πCgg), which is valid to non-planar devices [20]. RC delay and RF FoM are logged and then standardized to improve the ML training as in [15].…”

Section: Device Structure and Simulation Methodsmentioning

confidence: 99%

Digital/Analog Performance Optimization of Vertical Nanowire FETs Using Machine Learning

et al. 2021

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Vertical nanowire field-effect transistors (NWFETs) have been optimized to maximize digital and analog performances using fully-calibrated TCAD and machine learning (ML) technique. Digital performance is quantified by RC delay (CggVdd/Ion, where Cgg is gate capacitance, Vdd is operation voltage, and Ion is on-state current) at the fixed off-state currents, and analog performance is quantified by the product of cutoff frequency (Ft) and transconductance efficiency (Gm/Ids). ML accurately predicted the geometry and doping parameters suggesting the best device performances. All the optimized NWFETs have larger drain diameters but smaller source diameters at the minimum of gate lengths, gate oxide thicknesses, drain junction gradients, and source/drain spacer lengths. Small source diameters are needed to tightly control the energy barrier to reduce the short-channel effects, whereas large drain diameters increase current drivability than Cgg. Small drain junction gradients increase the lateral electric field from source to drain, which increases the carrier velocity. Longer spacer lengths decrease both Ion and Cgg, but the Ion degradation is critical. These device characteristics validate the optimization results from ML, and ML-based optimization is fast and effective to maximize both digital and analog performances.

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“…Conventional FinFETs, which have recently been scaled down to 5-nm nodes, have almost reached physical limits in reducing fin thickness [1]. Thus, to improve gate controllability, nanosheet FETs (NSHFETs) with gate-allaround (GAA) structures have been actively developed for sub-3-nm nodes [1]- [3]. However, they will continue to face these down-scaling limitations in the future.…”

Section: Introductionmentioning

confidence: 99%

Device Design Guidelines of 3-nm Node Complementary FET (CFET) in Perspective of Electrothermal Characteristics

et al. 2022

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For the first time, device design guidelines for a 3-nm node complementary field-effect transistor (CFET), which vertically stacks n-type and p-type nanosheet MOSFETs with a shared gate, are investigated using calibrated 3-D technology computer-aided design (TCAD). Here, the optimal device dimensions of the CFETs for better inverter performance and thermal characteristics are studied. The electrothermal performance are investigated for various vertical dimension parameters of CFET, such as the number of stacked channels, vertical distance between nanosheet channels (D nsh ), distance of n/pMOS separation (D n/p ), and channel thicknesses (T nsh ). The results show that, unlike conventional CMOS, the reduction of D nsh and D n/p of CFET can effectively improve inverter performance without severe thermal degradation, although other dimensional parameters trigger a severe trade-off between different electrothermal parameters. The reduction of D nsh and D n/p decreases C eff with a lower metal via the height and gate fringing effect. However, the reduction in D nsh and D n/p does not change R eff ; therefore, both the operation frequency (f ) and power-product delay (PDP) can be improved. In the case of thermal characteristics, the reduction of D nsh and D n/p slightly increases both T max and R th because of thermal coupling but is negligible. Therefore, the reduction of D nsh and D n/p will be a key technique for the development of sub-3-nm CFET.INDEX TERMS Complementary FET (CFET), nanosheet FET (NSHFET), technology computer-aided design (TCAD), 3-nm technology node.

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Device Design Guideline of 5-nm-Node FinFETs and Nanosheet FETs for Analog/RF Applications

Cited by 31 publications

References 30 publications

Inner Spacer Engineering to Improve Mechanical Stability in Channel-Release Process of Nanosheet FETs

Inner Spacer Engineering to Improve Mechanical Stability in Channel-Release Process of Nanosheet FETs

Digital/Analog Performance Optimization of Vertical Nanowire FETs Using Machine Learning

Device Design Guidelines of 3-nm Node Complementary FET (CFET) in Perspective of Electrothermal Characteristics

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