412 research outputs found

    Electrostatic Discharge Protection Device for Digital Circuits and for Applications with Input/Output Bipolar Voltage Much Higher than the Core Circuit Power Supply

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    An electrostatic discharge (ESD) device and method is provided. The ESD device can comprise a substrate doped to a first conductivity type, an epitaxial region doped to the second conductivity type, and a first well doped to the first conductivity type disposed in the substrate. The first well can comprise a first region doped to the first conductivity type, a second region doped to a second conductivity type, and a first isolation region disposed between the first region and the second region. The ESD device can also comprise a second well doped to a second conductivity type disposed in the substrate adjacent to the first well, where the second well can comprise a third region doped to the first conductivity type, a fourth region doped to the second conductivity type, and a second isolation region disposed between the third region and the fourth region. Still further, the ESD device can include a first trigger contact and second trigger contact comprising highly doped regions of eith

    Design, Characterization And Compact Modeling Of Novel Silicon Controlled Rectifier (scr)-based Devices For Electrostatic Discha

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    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

    Fabrication of three terminal devices by ElectroSpray deposition of graphene nanoribbons

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    Electrospray deposition (ESD) in ambient conditions has been used to deposit graphene nanoribbons (GNRs) dispersed in liquid phase on different types of substrates, including ones suitable for electrical transport. The deposition process was controlled and optimized by using Raman spectroscopy, Scanning Probe Microscopies and Scanning Electron Microscopy. When deposited on graphitic electrodes, GNRs were used as semi-conducting channel in three terminal devices showing gate tunability of the electrical current. These results suggest that ESD technique can be used as an effective tool to deposit chemically synthesized GNRs onto substrates of interest for technological applications

    Design, Characterization And Analysis Of Electrostatic Discharge (esd) Protection Solutions In Emerging And Modern Technologies

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    Electrostatic Discharge (ESD) is a significant hazard to electronic components and systems. Based on a specific processing technology, a given circuit application requires a customized ESD consideration that includes the devices’ operating voltage, leakage current, breakdown constraints, and footprint. As new technology nodes mature every 3-5 years, design of effective ESD protection solutions has become more and more challenging due to the narrowed design window, elevated electric field and current density, as well as new failure mechanisms that are not well understood. The endeavor of this research is to develop novel, effective and robust ESD protection solutions for both emerging technologies and modern complementary metal–oxide–semiconductor (CMOS) technologies. The Si nanowire field-effect transistors are projected by the International Technology Roadmap for Semiconductors as promising next-generation CMOS devices due to their superior DC and RF performances, as well as ease of fabrication in existing Silicon processing. Aiming at proposing ESD protection solutions for nanowire based circuits, the dimension parameters, fabrication process, and layout dependency of such devices under Human Body Mode (HBM) ESD stresses are studied experimentally in company with failure analysis revealing the failure mechanism induced by ESD. The findings, including design methodologies, failure mechanism, and technology comparisons should provide practical knowhow of the development of ESD protection schemes for the nanowire based integrated circuits. Organic thin-film transistors (OTFTs) are the basic elements for the emerging flexible, printable, large-area, and low-cost organic electronic circuits. Although there are plentiful studies focusing on the DC stress induced reliability degradation, the operation mechanism of OTFTs iv subject to ESD is not yet available in the literature and are urgently needed before the organic technology can be pushed into consumer market. In this work, the ESD operation mechanism of OTFT depending on gate biasing condition and dimension parameters are investigated by extensive characterization and thorough evaluation. The device degradation evolution and failure mechanism under ESD are also investigated by specially designed experiments. In addition to the exploration of ESD protection solutions in emerging technologies, efforts have also been placed in the design and analysis of a major ESD protection device, diodetriggered-silicon-controlled-rectifier (DTSCR), in modern CMOS technology (90nm bulk). On the one hand, a new type DTSCR having bi-directional conduction capability, optimized design window, high HBM robustness and low parasitic capacitance are developed utilizing the combination of a bi-directional silicon-controlled-rectifier and bi-directional diode strings. On the other hand, the HBM and Charged Device Mode (CDM) ESD robustness of DTSCRs using four typical layout topologies are compared and analyzed in terms of trigger voltage, holding voltage, failure current density, turn-on time, and overshoot voltage. The advantages and drawbacks of each layout are summarized and those offering the best overall performance are suggested at the en

    On-die transient event sensors and system-level ESD testing

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    System level electrostatic discharge (ESD) testing of electronic products is a critical part of product certification. Test methods were investigated to develop system level ESD simulation models to predict soft-failures in a system with multiple sensors. These methods rely completely on measurements. The model developed was valid only for the linear operation range of devices within the system. These methods were applied to a commercial product and used to rapidly determine when a soft failure would occur. Attaching cables and probes to determine stress voltages and currents within a system, as in the previous study, is time-consuming and can alter the test results. On-chip sensors have been developed which allow the user to avoid using cables and probes and can detect an event along with the level, polarity, and location of a transient event seen at the I/O pad. The sensors were implemented with minimum area consumption and can be implemented within the spacer cell of an I/O pad. Some of the proposed sensors were implemented in a commercial test microcontroller and have been tested to successfully record the event occurrence, location, level, and polarity on that test microcontroller. System level tests were then performed on a pseudo-wearable device using the on-chip sensors. The measurements were successful in capturing the peak disturbance and counting the number of ESD events without the addition of any external measurement equipment. A modification of the sensors was also designed to measure the peak voltage on a trace or pin inside a complex electronic product. The peak current can also be found when the sensor is placed across a transient voltage suppressor with a known I-V curve. The peak level is transmitted wirelessly to a receiver outside the system using frequency-modulated magnetic or electric fields, thus allowing multiple measurements to be made without opening the enclosure or otherwise modifying the system. Simulations demonstrate the sensors can accurately detect the peak transient voltage and transmit the level to an external receiver --Abstract, page iv

    Wireless Neurosensor for Full-Spectrum Electrophysiology Recordings during Free Behavior

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    SummaryBrain recordings in large animal models and humans typically rely on a tethered connection, which has restricted the spectrum of accessible experimental and clinical applications. To overcome this limitation, we have engineered a compact, lightweight, high data rate wireless neurosensor capable of recording the full spectrum of electrophysiological signals from the cortex of mobile subjects. The wireless communication system exploits a spatially distributed network of synchronized receivers that is scalable to hundreds of channels and vast environments. To demonstrate the versatility of our wireless neurosensor, we monitored cortical neuron populations in freely behaving nonhuman primates during natural locomotion and sleep-wake transitions in ecologically equivalent settings. The interface is electrically safe and compatible with the majority of existing neural probes, which may support previously inaccessible experimental and clinical research

    Advances in Solid State Circuit Technologies

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    This book brings together contributions from experts in the fields to describe the current status of important topics in solid-state circuit technologies. It consists of 20 chapters which are grouped under the following categories: general information, circuits and devices, materials, and characterization techniques. These chapters have been written by renowned experts in the respective fields making this book valuable to the integrated circuits and materials science communities. It is intended for a diverse readership including electrical engineers and material scientists in the industry and academic institutions. Readers will be able to familiarize themselves with the latest technologies in the various fields

    Design, Simulation and Characterization of Novel Electrostatic Discharge Protection Devices and Circuits in Advanced Silicon Technologies

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    Electrostatic Discharge (ESD) has been one of the major reliability concerns in the advanced silicon technologies and it becomes more important with technology scaling. It has been reported that more than 35% of the failures in integrated circuits (ICs) are ESD induced. ESD event is a phenomenon that a finite amount of charges transfer between two objects with different potential in a quite short time. Such event contains a large energy and the ICs without proper ESD protection could be destroyed easily, so ESD protection solutions are essential to semiconductor industry. ESD protection design consists of on-chip and off-chip ESD protection design, and the research works in this dissertation are all conducted in on-chip level, which incorporate the ESD protection devices and circuits into the microchip, to provide with basic ESD protection from manufacturing to customer use. The basic idea of ESD protection design is to provide a path with low impedance which directs most of the ESD current to flow through itself instead of the core circuit, and the ESD protection path must be robust enough to make sure that it does not fail before the core circuit. In this way, proper design on protection devices and circuits should be considered carefully. To assist the understanding and design of ESD protection, the ESD event in real world has been classified into a few ESD model including Human Body Model (HBM), Machine Model (MM), Charged Device Model (CDM), etc. Some mainstream testing method and industry standard are also introduced, including Transmission Line Pulse (TLP), and IEC 61000-4-2. ESD protection devices including diode, Gate-Grounded N-type MOSFET (GGNMOS), Silicon Controlled Rectifier (SCR) are basic elements for ESD protection design. In this dissertation, the device characteristics in ESD event and their applications are introduced. From the perspective of the whole chip ESD protection design, the concept of circuit level ESD protection and the ESD clamps are also briefly introduced. Technology Computer Aided Design (TCAD) and Simulation Program with Integrated Circuit Emphasis (SPICE) simulation is widely used in ESD protection design. In this dissertation, TCAD and SPICE simulation are carried out for a few times for both of pre-tapeout evaluation on characteristics of the proposed device and circuit and post-tapeout analysis on structure operating mechanism. Automotive electronics has been a popular subject in semiconductor industry, and due to the special requirement of the automotive applications like the capacitive pins, the ESD protection device used in such applications need to be specially designed. In this dissertation, a few SCRs without snapback are discussed in detail. To avoid core circuit damages caused the displacement current induced by the large snapback in conventional SCR, an eliminated/minimized snapback is preferred in a selection of the protection device. Two novel SCRs are proposed for High Voltage (HV), Medium Voltage (MV), and Low Voltage (LV) automotive ESD protection. The typical operating temperature for ICs is up to 125°C, however in automotive applications, the operating temperature may extend up to 850°C. In this way, the characteristics of the ESD protection device under the elevated temperatures will be an essential part to investigate for automotive ESD protection design. In this dissertation, the high temperature characteristics of ESD protection devices including diode and a few SCRs is measured and discussed in detail. TCAD simulation are also conducted to explain the underlying physical mechanism. This work provides with a useful insight and information to ESD protection design in high temperature applications. Besides the high temperature environment, ESD protection are also highly needed for electronics working in other extreme environment like the space. Space is an environment that contains kinds of radiation source and at the same time can generate abundant ESD. The ESD adhering to the space systems could be a potential threat to the space electronics. At the same time, the characteristics of the ESD protection part especially the basic protection device used in the space electronics could be influenced after the irradiation in the space. Therefore, the investigation of the radiation effects on ESD protection devices are necessary. In this dissertation, the total ionizing dose (TID) effects on ESD protection devices are investigated. The devices are irradiated with 1.5 MeV He+ and characterized with TLP tester. The pre- and post-irradiation characteristics are compared and the variation on key ESD parameters are analyzed and discussed. This work offers a useful insight on ESD devices\u27 operation under TID and help with the device designing on ESD protection devices for space electronics. Single ESD protection devices are essential part constructing the ESD protection network, however the optimization on ESD clamp circuit design is also important on building an efficient whole chip ESD protection network. In this dissertation, the design and simulation of a novel voltage triggered ESD detection circuit are introduced. The voltage triggered ESD detection circuit is proposed in a 0.18 um CMOS technology. Comparing with the conventional RC based detection circuit, the proposed circuit realizes a higher triggering efficiency with a much smaller footprint, and is immune to false triggering under fast power-up events. The proposed circuit has a better sensitivity to ESD event and is more reliable in ESD protection applications. The leakage current has been a concern with the scaling down of the thickness of the gate oxide. Therefore, a proper design of the ESD clamp for power rail ESD protection need to be specially considered. In this dissertation, a design of a novel ESD clamp with low leakage current is analyzed. The proposed clamp realized a pretty low leakage current up to 12 nA, and has a smaller footprint than conventional design. It also has a long hold-on time under ESD event and a quick turn-off mechanism for false triggering. SPICE simulation is carried out to evaluate the operation of the proposed ESD clamp

    MR4RF: MEM-device with impedance and their usage with impedance matching networks for passive RFID tags in the UHF

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    The passive RFID tag in the UHF has been employed in several different applications including, tracking, logistics, and as a sensing platform for the Internet of things (IoT). The tag is ideal for this industry due to its unique design. It harvests all of its energy from the environment, and is small, cheap, and requires little to no maintenance. However, there are two major issues limiting the potential of the passive RFID systems: the limited power harvested by the tag, and the high susceptibility to interference and coupling. In particular, dynamic environments render the traditionally fixed, RF impedance matching network ineffective. A novel design for a flexible Impedance-Switching Network (ISN) for passive RFID tags in the UHF is presented in this thesis. This novel approach can maximize power harvested by the tag. We propose two approaches to implementing the ISN. First, a more traditional design with a series of varactors is developed and studied. Each varactor is placed in parallel impedance lanes that are controlled via a feedback loop to maximize harvested power. A four-lane ISN is designed, tested, and tuned. The simulations and experiments demonstrate that ISN is capable of compensating for negative effect of mutual coupling in a ferromagnetic-reach environment. The second design employs a new material called a memristive switch that can replace the varactors in the ISN. State of a memristive switch is non-volatile and requires little energy to operate, thus making it ideal for passive RFID tags. We are the first to characterize the Co3O4 based memristive switch in UHF range. The results show that it can be employed as a varying capacitor in the RF front-end design. We propose three general configurations for the ISNs --Abstract, page iii

    Design And Characterization Of Noveldevices For New Generation Of Electrostaticdischarge (esd) Protection Structures

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    The technology evolution and complexity of new circuit applications involve emerging reliability problems and even more sensitivity of integrated circuits (ICs) to electrostatic discharge (ESD)-induced damage. Regardless of the aggressive evolution in downscaling and subsequent improvement in applications\u27 performance, ICs still should comply with minimum standards of ESD robustness in order to be commercially viable. Although the topic of ESD has received attention industry-wide, the design of robust protection structures and circuits remains challenging because ESD failure mechanisms continue to become more acute and design windows less flexible. The sensitivity of smaller devices, along with a limited understanding of the ESD phenomena and the resulting empirical approach to solving the problem have yielded time consuming, costly and unpredictable design procedures. As turnaround design cycles in new technologies continue to decrease, the traditional trial-and-error design strategy is no longer acceptable, and better analysis capabilities and a systematic design approach are essential to accomplish the increasingly difficult task of adequate ESD protection-circuit design. This dissertation presents a comprehensive design methodology for implementing custom on-chip ESD protection structures in different commercial technologies. First, the ESD topic in the semiconductor industry is revised, as well as ESD standards and commonly used schemes to provide ESD protection in ICs. The general ESD protection approaches are illustrated and discussed using different types of protection components and the concept of the ESD design window. The problem of implementing and assessing ESD protection structures is addressed next, starting from the general discussion of two design methods. The first ESD design method follows an experimental approach, in which design requirements are obtained via fabrication, testing and failure analysis. The second method consists of the technology computer aided design (TCAD)-assisted ESD protection design. This method incorporates numerical simulations in different stages of the ESD design process, and thus results in a more predictable and systematic ESD development strategy. Physical models considered in the device simulation are discussed and subsequently utilized in different ESD designs along this study. The implementation of new custom ESD protection devices and a further integration strategy based on the concept of the high-holding, low-voltage-trigger, silicon controlled rectifier (SCR) (HH-LVTSCR) is demonstrated for implementing ESD solutions in commercial low-voltage digital and mixed-signal applications developed using complementary metal oxide semiconductor (CMOS) and bipolar CMOS (BiCMOS) technologies. This ESD protection concept proposed in this study is also successfully incorporated for implementing a tailored ESD protection solution for an emerging CMOS-based embedded MicroElectroMechanical (MEMS) sensor system-on-a-chip (SoC) technology. Circuit applications that are required to operate at relatively large input/output (I/O) voltage, above/below the VDD/VSS core circuit power supply, introduce further complications in the development and integration of ESD protection solutions. In these applications, the I/O operating voltage can extend over one order of magnitude larger than the safe operating voltage established in advanced technologies, while the IC is also required to comply with stringent ESD robustness requirements. A practical TCAD methodology based on a process- and device- simulation is demonstrated for assessment of the device physics, and subsequent design and implementation of custom P1N1-P2N2 and coupled P1N1-P2N2//N2P3-N3P1 silicon controlled rectifier (SCR)-type devices for ESD protection in different circuit applications, including those applications operating at I/O voltage considerably above/below the VDD/VSS. Results from the TCAD simulations are compared with measurements and used for developing technology- and circuit-adapted protection structures, capable of blocking large voltages and providing versatile dual-polarity symmetric/asymmetric S-type current-voltage characteristics for high ESD protection. The design guidelines introduced in this dissertation are used to optimize and extend the ESD protection capability in existing CMOS/BiCMOS technologies, by implementing smaller and more robust single- or dual-polarity ESD protection structures within the flexibility provided in the specific fabrication process. The ESD design methodologies and characteristics of the developed protection devices are demonstrated via ESD measurements obtained from fabricated stand-alone devices and on-chip ESD protections. The superior ESD protection performance of the devices developed in this study is also successfully verified in IC applications where the standard ESD protection approaches are not suitable to meet the stringent area constraint and performance requirement
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