Improving ESD Protection Robustness Using SiGe Source/Drain Regions in Tunnel FET

Yang, Zhenchuan; Yang, Yuan; Yu, Ningmei; Liou, Juin J.

doi:10.3390/mi9120657

Cited by 7 publications

(5 citation statements)

References 28 publications

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“…Figure 2a,b are schematic diagrams of SiGe S/D PNN TFET and Conventional TFET, both of which have SiGe Source/Drain. In order to facilitate heat dissipation, the device size is not set to a very small value [27,28]. The high K material of the gate medium is HfO2.…”

Section: Basic Concept Of Electrostatic Discharge (Esd) Protection Tfetmentioning

confidence: 99%

Electrostatic Discharge Characteristics of SiGe Source/Drain PNN Tunnel FET

Wang

Mao

et al. 2021

Electronics

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Gate-grounded tunnel field effect transistors (ggTFETs) are considered as basic electrostatic discharge (ESD) protection devices in TFET-integrated circuits. ESD test method of transmission line pulse is used to deeply analyze the current characteristics and working mechanism of Conventional TFET ESD impact. On this basis, a SiGe Source/Drain PNN (P+N+N+) tunnel field effect transistors (TFET) was proposed, which was simulated by Sentaurus technology computer aided design (TCAD) software. Simulation results showed that the trigger voltage of SiGe PNN TFET was 46.3% lower, and the failure current was 13.3% higher than Conventional TFET. After analyzing the simulation results, the parameters of the SiGe PNN TFET were optimized. The single current path of the SiGe PNN TFET was analyzed and explained in the case of gate grounding.

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Section: Basic Concept Of Electrostatic Discharge (Esd) Protection Tfetmentioning

confidence: 99%

Electrostatic Discharge Characteristics of SiGe Source/Drain PNN Tunnel FET

Wang

Mao

et al. 2021

Electronics

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“…The quasi-statistic characteristics are obtained by averaging the transient data in an interval of 60 to 90 ns. According to [18,19], the lattice temperature is usually used as the criterion to determine device failure in simulations. The critical failure temperature is usually defined as a value that is hundreds of degrees kelvin lower than the melting temperature.…”

Section: Btbt Genmentioning

confidence: 99%

“…In the simulation, the current pulse has a rise time of 10 ns and a pulse width of 100 ns to mimic the human body model ESD event [12,14] The quasi-statistic characteristics are obtained by averaging the transient data in an interval of 60 to 90 ns. According to [18,19], the lattice temperature is usually used as the criterion to determine device failure in simulations. The critical failure temperature is usually defined as a value that is hundreds of degrees kelvin lower than the melting temperature The critical failure temperatures of the full-silicon TFET and Ge-source TFET in the simulation are set to 1200 and 890 K, respectively.…”

Section: Btbt Genmentioning

confidence: 99%

Optimization of Tunnel Field-Effect Transistor-Based ESD Protection Network

et al. 2021

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The tunnel field-effect transistor (TFET) is a potential candidate for replacing the reverse diode and providing a secondary path in a whole-chip electrostatic discharge (ESD) protection network. In this paper, the ESD characteristics of a traditional point TFET, a line TFET and a Ge-source TFET are investigated using technology computer-aided design (TCAD) simulations, and an improved TFET-based whole-chip ESD protection scheme is proposed. It is found that the Ge-source TFET has a lower trigger voltage and higher failure current compared to the traditional point and line TFETs. However, the Ge-source TFET-based secondary path in the whole-chip ESD protection network is more vulnerable compared to the primary path due to the low thermal instability. Simulation results show that choosing the proper germanium mole fraction in the source region can balance the discharge ability and thermal failure risk, consequently enhancing the whole-chip ESD robustness.

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“…(5)(6)(7) One of the advantages of TEFTs is that they are compatible with CMOS technology; thus, the concept of mixed MOSFET-TFET circuits was proposed and some new applications such as electrostatic discharge (ESD) protection with a TFET have been investigated. (8)(9)(10)(11)(12)(13)(14) It was found that a TFET can be a better choice than a shallow trench isolation (STI) diode in a whole-chip ESD protection network. (10) Recently, an increasing number of IC failures have been observed under power-on ESD and electrical overstress (EOS) conditions.…”

Section: Introductionmentioning

confidence: 99%

Characteristics of Tunnel Field-effect Transistors under Power-on Electrostatic Discharge and Electrical Overstress Conditions

Yang¹,

Mao²,

Zhang³

et al. 2020

Sensors and Materials

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The power-on electrostatic discharge (ESD) and electrical overstress (EOS) events are causing an increasing number of failures in modern integrated circuits (ICs). Tunnel field-effect transistors (TFETs) are considered as a better choice than shallow trench isolation diodes in whole-chip ESD protection networks. We have investigated the characteristics of TFETs under power-on ESD and EOS conditions by numerical simulation. The impact of an elevated ambient temperature, variations in current rise time and discharge duration, and the device structure on the triggering voltage and failure current are evaluated. The obtained results are discussed with detailed physical insights.

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Improving ESD Protection Robustness Using SiGe Source/Drain Regions in Tunnel FET

Cited by 7 publications

References 28 publications

Electrostatic Discharge Characteristics of SiGe Source/Drain PNN Tunnel FET

Electrostatic Discharge Characteristics of SiGe Source/Drain PNN Tunnel FET

Optimization of Tunnel Field-Effect Transistor-Based ESD Protection Network

Characteristics of Tunnel Field-effect Transistors under Power-on Electrostatic Discharge and Electrical Overstress Conditions

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