Polarity control in double-gate, gate-all-around vertically stacked silicon nanowire FETs

Marchi, Michele De; Sacchetto, Davide; Frache, Stefano; Zhang, J.; Gaillardon, P.-E.; Leblebici, Yusuf; Micheli, Giovanni De

doi:10.1109/iedm.2012.6479004

Cited by 250 publications

(250 citation statements)

References 9 publications

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“…DIG ambipolar FETs have been reported in some emerging technologies such as carbon nanotubes [12], graphene [13] and Silicon NanoWires (SiNWs) [14]. Among these technologies, SiNWs have a CMOS compatible fabrication process that can be easily integrated by the semiconductor industry [15].…”

Section: Ambipolar Sinwfet Ambipolar Transistors Are Double Indepmentioning

confidence: 99%

Self-checking ripple-carry adder with Ambipolar Silicon NanoWire FET

Turkyilmaz

Clermidy

Amarù

et al. 2013

2013 IEEE International Symposium on Circuits and Systems (ISCAS2013)

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Abstract-For the rapid adoption of new and aggressive technologies such as ambipolar Silicon NanoWire (SiNW), addressing fault-tolerance is necessary. Traditionally, transient fault detection implies large hardware overhead or performance decrease compared to permanent fault detection. In this paper, we focus on on-line testing and its application to ambipolar SiNW. We demonstrate on self-checking ripple-carry adder how ambipolar design style can help reduce the hardware overhead. When compared with equivalent CMOS process, ambipolar SiNW design shows a reduction in area of at least 56% (28%) with a decreased delay of 62% (6%) for Static (Transmission Gate) design style.

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Section: Ambipolar Sinwfet Ambipolar Transistors Are Double Indepmentioning

confidence: 99%

Self-checking ripple-carry adder with Ambipolar Silicon NanoWire FET

Turkyilmaz

Clermidy

Amarù

et al. 2013

2013 IEEE International Symposium on Circuits and Systems (ISCAS2013)

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“…Instead of the conventional selective doping process, reconfigurable FET technologies can change polarity (n-or p-type) during operation by setting a polarity gate electrode (PG) bias [3,4,5,6]. The type of charge carrier for the conduction is determined by the appropriate gate voltage tuning at the Schottky junction of the source region.…”

Section: Reconfigurable Operationmentioning

confidence: 99%

“…Unlike to the conventional complementary metal-oxide-semiconductor (CMOS) devices which have static electrical functions determined during the fabrication, reconfigurable FETs (RFETs) are dynamically programmable to n-or p-type FET by changing electric signals during the operation. Thus, it is desirable for the highly adaptable logic architectures with their enhanced functionality [3,4,5,6]. Reducing the power consumption is another technical issue for future logic device technology.…”

Section: Introductionmentioning

confidence: 99%

Reconfigurable U-shaped tunnel field-effect transistor

Lee

kwon

Choi

et al. 2017

IEICE Electron. Express

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A reconfigurable U-shaped tunnel field-effect transistor (RUT-FET) is proposed as a low-power dynamically programmable logic device. It has several advantages over conventional reconfigurable TFETs: 1) Excellent scalability without any degradation of subthreshold swing (SS) and draininduced barrier thinning (DIBT) with recessed channel structure. 2) High current drivability with increased band-to-band tunneling junction 3) Scaling of SS with tunneling barrier width defined by geometrical parameters. In this manuscript, its electrical characteristics are examined by technology computer-aided design (TCAD) simulation. It shows ∼30× higher ON-state current than control devices and 41.8 mV/dec-SS during drain current increase by five orders magnitude. The reconfigurable operations for nand p-type FETs are also discussed.

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“…Various new technologies, such as FinFETs [4,7], and tunnel-FETs [8], have been developed in recent years to enable the continuation of Moore's law [9], but further development with current technologies are uncertain [10]. Other options are being explored as alternatives, which include semiconductor nanowire (SNW) based FETs [11][12][13], FETs comprised of 2D materials [14,15], and FETs with sophisticated gate structures [16], such as multiple independent gates [5,6] or a gate with embedded ferroelectric material [17]. There is, however, no clear pathway for overcoming a FET's intrinsic physical limitations [18][19][20] dictated by its operation mechanism, such as random dopant fluctuations [3] and gate fabrication complexities [21], and no viable rival technology currently exists.…”

Section: Introductionmentioning

confidence: 99%

“…Although FETs have evolved structurally from early planar to their current 3D geometries in parallel with the continual shrinkage of its lateral size, the basic operating principle remains the same. This has led to ever greater fabrication complexity, and ultimately to challenges in gate fabrication and doping control [2][3][4][5][6]. Various new technologies, such as FinFETs [4,7], and tunnel-FETs [8], have been developed in recent years to enable the continuation of Moore's law [9], but further development with current technologies are uncertain [10].…”

Section: Introductionmentioning

confidence: 99%

Light-Effect Transistor (LET) with Multiple Independent Gating Controls for Optical Logic Gates and Optical Amplification

et al. 2016

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Modern electronics are developing electronic-optical integrated circuits, while their electronic backbone, e.g., field-effect transistors (FETs), remains the same. However, further FET down scaling is facing physical and technical challenges. A light-effect transistor (LET) offers electronic-optical hybridization at the component level, which can continue Moore's law to the quantum region without requiring a FET's fabrication complexity, e.g., physical gate and doping, by employing optical gating and photoconductivity. Multiple independent gates are therefore readily realized to achieve unique functionalities without increasing chip space. Here we report LET device characteristics and novel digital and analog applications, such as optical logic gates and optical amplification. Prototype CdSe-nanowire-based LETs show output and transfer characteristics resembling advanced FETs, e.g., on/off ratios up to ∼1.0 × 10 6 with a source-drain voltage of ∼1.43 V, gate-power of ∼260 nW, and a subthreshold swing of ∼0.3 nW/decade (excluding losses). Our work offers new electronic-optical integration strategies and electronic and optical computing approaches.

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Polarity control in double-gate, gate-all-around vertically stacked silicon nanowire FETs

Cited by 250 publications

References 9 publications

Self-checking ripple-carry adder with Ambipolar Silicon NanoWire FET

Self-checking ripple-carry adder with Ambipolar Silicon NanoWire FET

Reconfigurable U-shaped tunnel field-effect transistor

Light-Effect Transistor (LET) with Multiple Independent Gating Controls for Optical Logic Gates and Optical Amplification

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