Review on analog/radio frequency performance of advanced silicon MOSFETs

Passi, Vikram; Raskin, Jean‐Pierre

doi:10.1088/1361-6641/aa9145

Cited by 37 publications

(18 citation statements)

References 153 publications

(169 reference statements)

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“…Since DC parameters were well calibrated, G m R o of FinFETs and NSFETs were reasonable within the measured data [10], [11], [23]- [25]. F t and F max were slightly larger than the measured data [10], [11], [23]- [25] because the parasitic RC components of metal interconnects are not included in this TCAD work. But FinFETs and NSFETs would have the same metal-line configurations under the same CPP.…”

Section: Device Structure and Simulation Methodssupporting

confidence: 54%

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

Yoon

Baek

2020

IEEE Access

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Analog/RF performances of 5-nm node bulk fin-shaped field-effect transistors (FinFETs) and nanosheet FETs (NSFETs) were investigated and compared thoroughly using fully-calibrated TCAD. NSFETs have greater current drivability and gate-to-channel controllability than FinFETs under the same footprint, thus achieving larger intrinsic gain. But the cutoff frequencies (F t) of FinFETs and NSFETs are comparable due to larger gate capacitances (C gg) of NSFETs compensating DC performance improvements. Gate resistances (R g) of NSFETs are larger because of their metal gate (MG) configuration surrounding the channels, longer MG height by the topmost NS spacing region, and the bottom transistor, thus degrading maximum oscillation frequency (F max). Device design guidelines of FinFETs and NSFETs are also studied for better intrinsic gain, F t , and F max. Intrinsic gain is improved by better electrostatics, whereas F t increases by greater current drivability over C gg. For larger F max , careful device design is required to compensate between R g , C gg , output resistance, and F t. Overall, NSFETs outperform FinFETs in terms of intrinsic gain, F t , and F max , thus NSFETs are promising for analog/RF applications.

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Section: Device Structure and Simulation Methodssupporting

confidence: 54%

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

Yoon

Baek

2020

IEEE Access

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“…ultra-high carrier mobility (2×10 5 cm 2 /Vs) and a high saturation velocity (~5.5×10 7 cm/s) [1][2][3][4][5][6][7]. The field-effect transistor (FET) is an important component of any RF circuit embedded in the modern information and communication systems, and thus, improvements of its performance have a critical impact on this field [7][8][9]. Indeed, very auspicious RF graphene field-effect transistors (GFETs) have already been demonstrated [10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Unveiling the impact of the bias-dependent charge neutrality point on graphene based multi-transistor applications

et al. 2021

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The Dirac voltage of a graphene field-effect transistor (GFET) stands for the gate bias that sets the charge neutrality condition in the channel, thus resulting in a minimum conductivity. Controlling its dependence on the terminal biases is crucial for the design and optimization of radio-frequency applications based on multiple GFETs. However, the previous analysis of such dependence carried out for single devices is uncomplete and if not properly understood could result in circuit designs with poor performance. The control of the Dirac point shift (DPS) is particularly important for the deployment of graphene-based differential circuit topologies where keeping a strict symmetry between the electrically balanced branches is essential for exploiting the advantages of such topologies. This note sheds light on the impact of terminal biases on the DPS in a real device and sets a rigorous methodology to control it so to eventually optimize and exploit the performance of radio-frequency applications based on GFETs.

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“…Figure of Merits (FoMs) for analog performance of a DGFET can be described by: transconductance (g m = ∂I ds /∂V gs ), transconductance generation factor (g m /I ds ), intrinsic gain (A vo = g m /g ds ), and early voltage (V EA = I ds /g ds ) [33]. Since, g m influences the intrinsic voltage gain of a device, hence, considered as a key parameter for analog applications in the current study.…”

Section: Foms For Analog Applicationsmentioning

confidence: 99%

“…The f T is a frequency when the current gain is unity, whereas the f MAX is a frequency when power gain is unity. The NF min is evaluated by dividing the signal-to-noise ratio at the input port to that of the output port and is a measure of high-frequency noise [33], [37]- [39].…”

Section: Foms For Rf Applicationsmentioning

confidence: 99%

Analog/RF Performance Investigation of Dopingless FET for Ultra-Low Power Applications

Sirohi¹,

Sahu

Singh³

2019

IEEE Access

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In this paper, we investigated the performance of a dopingless (DL) double gate fieldeffect transistor (DL-DGFET) for ultra-low power (ULP) analog/RF applications. It is observed that the source/drain metal electrode workfunction engineering in DL-DGFET yields improved analog/RF performance as compared to underlap inversion mode (IM) and junctionless (JL) DGFETs. The DL-DGFET exhibits superior electrostatic control, low threshold voltage variability, simpler fabrication process, and comparable ON state current as compared to IM-and JL-DGFETs. In addition, the DL-DGFET alleviates the inherent contradictory trade-off between gain and bandwidth by exhibiting the simultaneous improvement in intrinsic voltage gain (A vo ) and unity gain cutoff frequency (f T ). The well calibrated TCAD simulation results of the DL-DGFET show a minimum noise figure (NF min ) 1.27 times and 2.29 times less than the IM and JL-DGFET. At gate overdrive voltage of 0.1 V, the DL-DGFET achieves 5.08 times f T and 5.86 times maximum oscillation frequency (f MAX ) along with 3.59 times A vo in comparison to JL-DGFET. From simulation results, it is evident that the dopingless FET is a promising candidate for ultra-low power applications of analog and radio frequency (RF) domains.INDEX TERMS Charge-plasma, doping-less, transconductance, minimum noise figure, ultra low power (ULP).

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Review on analog/radio frequency performance of advanced silicon MOSFETs

Cited by 37 publications

References 153 publications

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

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

Unveiling the impact of the bias-dependent charge neutrality point on graphene based multi-transistor applications

Analog/RF Performance Investigation of Dopingless FET for Ultra-Low Power Applications

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