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Design, Characterization And Compact Modeling Of Novel Silicon Controlled Rectifier (scr)-based Devices For Electrostatic DischaLou, Lifang 01 January 2008 (has links)
Electrostatic Discharge (ESD), an event of a sudden transfer of electrons between two bodies at different potentials, happens commonly throughout nature. When such even occurs on integrated circuits (ICs), ICs will be damaged and failures result. As the evolution of semiconductor technologies, increasing usage of automated equipments and the emerging of more and more complex circuit applications, ICs are more sensitive to ESD strikes. Main ESD events occurring in semiconductor industry have been standardized as human body model (HBM), machine model (MM), charged device model (CDM) and international electrotechnical commission model (IEC) for control, monitor and test. In additional to the environmental control of ESD events during manufacturing, shipping and assembly, incorporating on-chip ESD protection circuits inside ICs is another effective solution to reduce the ESD-induced damage. This dissertation presents design, characterization, integration and compact modeling of novel silicon controlled rectifier (SCR)-based devices for on-chip ESD protection. The SCR-based device with a snapback characteristic has long been used to form a VSS-based protection scheme for on-chip ESD protection over a broad rang of technologies because of its low on-resistance, high failure current and the best area efficiency. The ESD design window of the snapback device is defined by the maximum power supply voltage as the low edge and the minimum internal circuitry breakdown voltage as the high edge. The downscaling of semiconductor technology keeps on squeezing the design window of on-chip ESD protection. For the submicron process and below, the turn-on voltage and sustain voltage of ESD protection cell should be lower than 10 V and higher than 5 V, respectively, to avoid core circuit damages and latch-up issue. This presents a big challenge to device/circuit engineers. Meanwhile, the high voltage technologies push the design window to another tough range whose sustain voltage, 45 V for instance, is hard for most snapback ESD devices to reach. Based on the in-depth elaborating on the principle of SCR-based devices, this dissertation first presents a novel unassisted, low trigger- and high holding-voltage SCR (uSCR) which can fit into the aforesaid ESD design window without involving any extra assistant circuitry to realize an area-efficient on-chip ESD protection for low voltage applications. The on-chip integration case is studied to verify the protection effectiveness of the design. Subsequently, this dissertation illustrate the development of a new high holding current SCR (HHC-SCR) device for high voltage ESD protection with increasing the sustain current, not the sustain voltage, of the SCR device to the latchup-immune level to avoid sacrificing the ESD protection robustness of the device. The ESD protection cells have been designed either by using technology computer aided design (TCAD) tools or through trial-and-error iterations, which is cost- or time-consuming or both. Also, the interaction of ESD protection cells and core circuits need to be identified and minimized at pre-silicon stage. It is highly desired to design and evaluate the ESD protection cell using simulation program with integrated circuit emphasis (SPICE)-like circuit simulation by employing compact models in circuit simulators. And the compact model also need to predict the response of ESD protection cells to very fast transient ESD events such as CDM event since it is a major ESD failure mode. The compact model for SCR-based device is not widely available. This dissertation develops a macromodeling approach to build a comprehensive SCR compact model for CDM ESD simulation of complete I/O circuit. This modeling approach offers simplicity, wide availability and compatibility with most commercial simulators by taking advantage of using the advanced BJT model, Vertical Bipolar Inter-Company (VBIC) model. SPICE Gummel-Poon (SGP) model has served the ICs industry well for over 20 years while it is not sufficiently accurate when using SGP model to build a compact model for ESD protection SCR. This dissertation seeks to compare the difference of SCR compact model built by using VBIC and conventional SGP in order to point out the important features of VBIC model for building an accurate and easy-CAD implement SCR model and explain why from device physics and model theory perspectives.
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Study and characterization of electrical overstress aggressors on integrated circuits and robustness optimization of electrostatic discharge protection devices / Etude et caractérisation des agresseurs électriques de sur-résistance sur les circuits intégrés et optimisation de la robustesse des dispositifs de protection contre les décharges électrostatiquesLoayza Ramirez, Jorge Miguel 08 June 2017 (has links)
Cette thèse de doctorat s’inscrit dans la thématique de la fiabilité des circuits intégrés dans l’industrie de la microélectronique. Un circuit intégré peut être exposé à des agresseurs électriques potentiellement dangereux pendant toute sa durée de vie. Idéalement, les circuits devraient pouvoir encaisser ces excès d’énergie sans perdre leur fonctionnalité. En réalité, des défaillances peuvent être observées lors de tests de qualification ou en application finale. Il est donc dans l’intérêt des fabricants de réduire ces défaillances. Actuellement, il existe des circuits de protection sur puce conçus pour dévier l’énergie de ces agresseurs à l’écart des composants fragiles. Le terme anglophone Electrical Overstress (EOS) englobe tous les agresseurs électriques qui dépassent une limite au-delà de laquelle les composants peuvent être détruits. La définition de ce terme est traitée en détail dans la thèse. L’objectif de cette thèse est de comprendre le statut du sujet des EOS dans l’industrie. On propose ensuite une nouvelle méthodologie de caractérisation de circuits pour quantifier leur robustesse face à des formes d’onde représentatives présélectionnées. On propose également des solutions de circuits de protection sur puce que ce soit au niveau de nouveaux composants actifs ou au niveau de la conception des circuits électroniques de protection. Par exemple on propose un nouveau composant basé sur le thyristor qui a la capacité de s’éteindre même si la tension d’alimentation est présente sur l’anode. Une autre proposition est de désactiver les circuits de protection face aux décharges électrostatiques lorsque les puces sont dans un environnement où l’on est sur ou ces agresseurs ne présentent plus de danger. Finalement, des perspectives du travail de thèse sont citées. / This Ph.D. thesis concerns reliability issues in the microelectronics industry for the most advanced technology nodes. In particular, the Electrical OverStress (EOS) issue is studied. Reducing EOS failures in Integrated Circuits (ICs) is becoming more and more important. However, the EOS topic is very complex and involves many different causes, viewpoints, definitions and approaches. In this context, a complete analysis of the current status of the EOS issue is carried out. Then, the Ph.D. objectives can be defined in a clear way. In particular, robustness increase of on-chip protection structures and IC characterization against EOS-like aggressors are two of the main goals. In order to understand and quantify the behavior of ICs against these aggressors, a dedicated EOS test bench is put in place along with the definition of a characterization methodology. A full characterization and comparison is performed on two different Electro- Static Discharge (ESD) power supply clamps. After identifying the potential weaknesses of the promising Silicon-Controlled Rectifier (SCR) device, a new SCR-based device with a turn-off capability is proposed and studied thanks to 3-D Technology Computer-Aided Design (TCAD)simulation. Triggering and turn-off behaviors are studied, as well as its optimization. Finally, three different approaches are proposed for improving the robustness of the IC onchip protection circuits. They are characterized thanks to the EOS test bench which allows identifying their assets as well as their points of improvement.
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