Current Search: breakdown (x)
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Title
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STUDY OF GATE OXIDE BREAKDOWN AND HOT ELECTRON EFFECT ON CMOS CIRCUIT PERFORMANCES.
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Creator
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MA, JUN, Yuan, Jiann S., University of Central Florida
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Abstract / Description
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In the modern semiconductor world, there is a significant scaling of the transistor dimensions The transistor gate length and the gate oxide thickness drop down to only several nanometers. Today the semiconductor industry is already dominated by submicron devices and other material devices for the high transistor density and performance enhancement. In this case, the semiconductor reliability issues are the most important thing for commercialization. The major reliability issues caused...
Show moreIn the modern semiconductor world, there is a significant scaling of the transistor dimensions The transistor gate length and the gate oxide thickness drop down to only several nanometers. Today the semiconductor industry is already dominated by submicron devices and other material devices for the high transistor density and performance enhancement. In this case, the semiconductor reliability issues are the most important thing for commercialization. The major reliability issues caused by voltage are hot carrier effects (HCs) and gate oxide breakdown (BD) effects. These issues are recently more important to industry, due to the small size and high lateral field in short-channel of the device will cause high electrical field and other reliability issues. This dissertation primarily focuses on the study of the CMOS device gate oxide breakdown effect on different kinds of circuits performance, also some HC effects on circuit's performance are studied. The physical mechanisms for BD have been presented. A practical and accurate equivalent breakdown circuit model for the CMOS device was studied to simulate the RF performance degradation on the circuit level. The BD location effect has been evaluated. Furthermore, a methodology was developed to predict the BD effects on the circuit's performances with different kinds of BD location. It also provides guidance for the reliability considerations of the digital, analog, and RF circuit design. The BD effects on digital circuits SRAM, analog circuits Sample&Hold, and RF building blocks with the nanoscale device low noise amplifier, LC oscillator, mixer, and power amplifier, have been investigated systematically. Finally 90 nm device will be used to study the HC effect on the circuit's performance. The contributions of this dissertation include: Providing a thorough study of the gate oxide breakdown issues caused by the voltage stress on the device from device level to circuit level; Studying real voltage stress case high frequency (950 MHz) dynamic stress, and comparing with the traditional DC stress; A simple, practical, and analytical method is derived to study the gate oxide breakdown effect including breakdown location effect and soft / hard breakdown on the digital, analog and RF circuits performances. A brief introduction and simulation for 90 nm device HC effect provide some useful information and helpful data for the industry. The gate oxide breakdown effect is the most common device reliability issue. The successful results of this dissertation, from device level to circuit level, provide an insight on how the BD affects the circuit's performance, and also provide some useful data for the circuit designers in their future work.
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Date Issued
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2009
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Identifier
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CFE0002856, ucf:48073
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Format
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Document (PDF)
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PURL
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http://purl.flvc.org/ucf/fd/CFE0002856
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Title
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RF Circuit Designs for Reliability and Process Variability Resilience.
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Creator
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Kritchanchai, Ekavut, Yuan, Jiann-Shiun, Sundaram, Kalpathy, Wei, Lei, Lin, Mingjie, Chow, Lee, University of Central Florida
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Abstract / Description
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Complementary metal oxide semiconductor (CMOS) radio frequency (RF) circuit design has been an ever-lasting research field. It has gained so much attention since RF circuits offer high mobility and wide-band efficiency, while CMOS technology provides the advantage of low cost and high integration capability. At the same time, CMOS device size continues to scale to the nanometer regime. Reliability issues with RF circuits have become more challenging than ever before. Reliability mechanisms,...
Show moreComplementary metal oxide semiconductor (CMOS) radio frequency (RF) circuit design has been an ever-lasting research field. It has gained so much attention since RF circuits offer high mobility and wide-band efficiency, while CMOS technology provides the advantage of low cost and high integration capability. At the same time, CMOS device size continues to scale to the nanometer regime. Reliability issues with RF circuits have become more challenging than ever before. Reliability mechanisms, such as gate oxide breakdown, hot carrier injection, negative bias temperature instability, have been amplified as the device size shrinks. In addition, process variability becomes a new design paradigm in modern RF circuits.In this Ph.D. work, a class F power amplifier (PA) was designed and analyzed using TSMC 180nm process technology. Its pre-layout and post-layout performances were compared. Post-layout parasitic effect decreases the output power and power-added efficiency. Physical insight of hot electron impact ionization and device self-heating was examined using the mixed-mode device and circuit simulation to mimic the circuit operating environment. Hot electron effect increases the threshold voltage and decreases the electron mobility of an n-channel transistor, which in turn decreases the output power and power-added efficiency of the power amplifier, as evidenced by the RF circuit simulation results. The device self-heating also reduces the output power and power-added efficiency of the PA. The process, voltage, and temperature (PVT) effects on a class AB power amplifier were studied. A PVT compensation technique using a current-source as an on-chip sensor was developed. The adaptive body bias design with the current sensing technique makes the output power and power-added efficiency much less sensitive to process variability, supply voltage variation, and temperature fluctuation, predicted by our derived analytical equations which are also verified by Agilent Advanced Design System (ADS) circuit simulation.Process variations and hot electron reliability on the mixer performance were also evaluated using different process corner models. The conversion gain and noise figure were modeled using analytical equations, supported by ADS circuit simulation results. A process invariant current source circuit was developed to eliminate process variation effect on circuit performance. Our conversion gain, noise figure, and output power show robust performance against PVT variations compared to those of a traditional design without using the current sensor, as evidenced by Monte Carlo statistical simulation.Finally, semiconductor process variations and hot electron reliability on the LC-voltage controlled oscillator (VCO) performance was evaluated using different process models. In our newly designed VCO, the phase noise and power consumptions are resilient against process variation effect due to the use of on-chip current sensing and compensation. Our Monte-Carlo simulation and analysis demonstrate that the standard deviation of phase noise in the new VCO design reduces about five times than that of the conventional design.
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Date Issued
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2016
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Identifier
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CFE0006131, ucf:51182
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Format
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Document (PDF)
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PURL
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http://purl.flvc.org/ucf/fd/CFE0006131
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Title
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Investigation of Breakdown Power During Electrical Breakdown of Aligned Array of Carbon Nanotubes.
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Creator
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Bhanu, Udai, Khondaker, Saiful, Leuenberger, Michael, Zhai, Lei, University of Central Florida
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Abstract / Description
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Massively parallel arrays of single walled carbon nanotubes (SWNT) have attracted significant research interests because of their ability to (i) average out inhomogeneities of individual SWNTs, (ii) provide larger on currents, and (iii) reduce noise to provide higher cutoff frequency for radio frequency applications. However, the array contains both metallic and semiconducting SWNTs and the presence of metallic nanotube in an aligned array negatively affects the device properties. Therefore,...
Show moreMassively parallel arrays of single walled carbon nanotubes (SWNT) have attracted significant research interests because of their ability to (i) average out inhomogeneities of individual SWNTs, (ii) provide larger on currents, and (iii) reduce noise to provide higher cutoff frequency for radio frequency applications. However, the array contains both metallic and semiconducting SWNTs and the presence of metallic nanotube in an aligned array negatively affects the device properties. Therefore, it is essential to selectively remove metallic nanotubes to obtain better transistor properties. It was recently found that although such a selective removal can be effective for a low density array, it does not work in a high density array and lead to a correlated breakdown of the entire array giving rise to a nanofissure pattern.In order to obtain a deeper understanding of such a correlated SWNT breakdown, we studied the breakdown power in the successive electrical breakdown of both low ( (<) 2 /um) and high density ((>)10 /um) SWNT arrays. We show that the breakdown voltage in successive electrical breakdown increases for low density array while it decreases for high density arrays. The estimated power required for the breakdown remains constant for low density arrays while it decreases for high density arrays in successive electrical breakdowns. We also show that, while a simple model of parallel resistor network can explain the breakdown of low density array, it cannot explain the behavior for the high density array implying that the correlation between the closely spaced parallel nanotubes plays a big role in the successive breakdowns of the high density SWNTs.
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Date Issued
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2012
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Identifier
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CFE0004518, ucf:49292
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Format
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Document (PDF)
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PURL
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http://purl.flvc.org/ucf/fd/CFE0004518
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Title
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STUDY OF OXIDE BREAKDOWN, HOT CARRIER AND NBTI EFFECTS ON MOS DEVICE AND CIRCUIT RELIABILITY.
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Creator
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Liu, Yi, Yuan, Jiann.S., University of Central Florida
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Abstract / Description
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As CMOS device sizes shrink, the channel electric field becomes higher and the hot carrier (HC) effect becomes more significant. When the oxide is scaled down to less than 3 nm, gate oxide breakdown (BD) often takes place. As a result, oxide trapping and interface generation cause long term performance drift and related reliability problems in devices and circuits. The RF front-end circuits include low noise amplifier (LNA), local oscillator (LO) and mixer. It is desirable for a LNA to...
Show moreAs CMOS device sizes shrink, the channel electric field becomes higher and the hot carrier (HC) effect becomes more significant. When the oxide is scaled down to less than 3 nm, gate oxide breakdown (BD) often takes place. As a result, oxide trapping and interface generation cause long term performance drift and related reliability problems in devices and circuits. The RF front-end circuits include low noise amplifier (LNA), local oscillator (LO) and mixer. It is desirable for a LNA to achieve high gain with low noise figure, a LO to generate low noise signal with sufficient output power, wide tuning range, and high stability, and a mixer to up-convert or down-convert the signal with good linearity. However, the RF front-end circuit performance is very sensitive to the variation of device parameters. The experimental results show that device performance is degraded significantly subject to HC stress and BD. Therefore, RF front-end performance is degraded by HC and BD effects. With scaling and increasing chip power dissipation, operating temperatures for device have also been increasing. Another reliability concern, which is the negative bias temperature instability (NBTI) caused by the interface traps under high temperature and negative gate voltage bias, arises when the operation temperature of devices increases. NBTI has received much attention in recent year and it is found that NIT is present for all stress conditions and NOT is found to occur at high VG. Therefore, the probability of BD in pMOSFET increases with temperature since trapped charges during the NBTI process increase, thus resulting in percolation, a main cause of oxide degradation. The above effects can cause significant degradations in transistors, thus leading to the shifts of RF performance. This dissertation focuses on the following aspects: (1) RF performance degradation in nMOSFET and pMOSFET due to hot carrier and soft breakdown effects are examined experimentally and will be used for circuit application in the future. (2) A modeling method to analyze the gate oxide breakdown effects on RF nMOSFET has been proposed. The device performance drifts due to gate oxide breakdown are examined, breakdown spot resistance and total gate capacitance are extracted before and after stress for 0.16 um CMOS technology. (3) LC voltage controlled oscillator (VCO) performance degradation due to gate oxide breakdown effect is evaluated. (4) NBTI, HCI and BD combined effects on RF performance degradation are investigated. A physical picture illustrating the NBTI induced BD process is presented. A model to evaluate the time-to-failure (TTF) during NBTI is developed. DCIV method is used to extract the densities of NIT and NOT. Measurements show that there is direct correlation between the steplike increase in the gate current and the oxide-trapped charge (NOT). However, Breakdown has nothing to do with interface traps (NIT). (5) It is found that the degradation due to NSH stress is more severe than that of NS stress at high temperature. A model aiming to evaluate the stress-induced degradation is also developed.
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Date Issued
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2005
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Identifier
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CFE0000505, ucf:46465
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Format
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Document (PDF)
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PURL
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http://purl.flvc.org/ucf/fd/CFE0000505
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Title
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CIRCUIT DESIGN AND RELIABILITY OF A CMOS RECEIVER.
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Creator
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Yang, Hong, Yuan, Jiann, University of Central Florida
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Abstract / Description
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This dissertation explores CMOS RF design and reliability for portable wireless receivers. The objective behind this research is to achieve an increase in integration level, and gain more understanding for RF reliability. The fields covered include device, circuit and system. What is under investigation is a multi-band multi-mode receiver with GSM, DCS-1800 and CDMA compatibility. To my understanding, GSM and CDMA dual-mode mobile phones are progressively investigated in industries, and few...
Show moreThis dissertation explores CMOS RF design and reliability for portable wireless receivers. The objective behind this research is to achieve an increase in integration level, and gain more understanding for RF reliability. The fields covered include device, circuit and system. What is under investigation is a multi-band multi-mode receiver with GSM, DCS-1800 and CDMA compatibility. To my understanding, GSM and CDMA dual-mode mobile phones are progressively investigated in industries, and few commercial products are available. The receiver adopts direct conversion architecture. Some improved circuit design methods are proposed, for example, for low noise amplifier (LNA). Except for band filters, local oscillators, and analog-digital converters which are usually implemented by COTS SAW filters and ICs, all the remaining blocks such as switch, LNA, mixer, and local oscillator are designed in MOSIS TSMC 0.35ìm technology in one chip. Meanwhile, this work discusses related circuit reliability issues, which are gaining more and more attention. Breakdown (BD) and hot carrier (HC) effects are important issues in semiconductor industry. Soft-breakdown (SBD) and HC effects on device and RF performance has been reported. Hard-breakdown (HBD) effects on digital circuits have also been investigated. This work uniquely address HBD effects on the RF device and circuit performance, taking low noise amplifier and power amplifier as targets.
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Date Issued
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2004
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Identifier
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CFE0000212, ucf:46259
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Format
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Document (PDF)
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PURL
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http://purl.flvc.org/ucf/fd/CFE0000212
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Title
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Design and Optimization of Superjunction Vertical DMOS Power Transistors using Sentaurus Device Simulation.
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Creator
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Mendoza Macias, Raul, Yuan, Jiann-Shiun, Sundaram, Kalpathy, Fan, Deliang, University of Central Florida
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Abstract / Description
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Vertical double-diffused metal oxide semiconductor (VDMOS) power transistor has been studied. The use of superjunction (SJ) in the drift region of VDMOS has been evaluated using three-dimensional device simulation. All relevant physical models in Sentaurus are turned on. The VDMOS device doping profile is obtained from process simulation. The superjunction VDMOS performance in off-state breakdown voltage and specific on-resistance is compared with that in conventional VDMOS structure. In...
Show moreVertical double-diffused metal oxide semiconductor (VDMOS) power transistor has been studied. The use of superjunction (SJ) in the drift region of VDMOS has been evaluated using three-dimensional device simulation. All relevant physical models in Sentaurus are turned on. The VDMOS device doping profile is obtained from process simulation. The superjunction VDMOS performance in off-state breakdown voltage and specific on-resistance is compared with that in conventional VDMOS structure. In addition, electrical parameters such as threshold voltage and charge balance are also examined. Increasing the superjunction doping in the drift region of VDMOS reduces the on-resistance by 26%, while maintaining the same breakdown voltage and threshold voltage compared to that of the conventional VDMOS power transistor with similar device design without using a superjunction.
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Date Issued
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2016
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Identifier
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CFE0006354, ucf:51525
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Format
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Document (PDF)
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PURL
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http://purl.flvc.org/ucf/fd/CFE0006354
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Title
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CLASS-E CASCODE POWER AMPLIFIER ANALYSIS AND DESIGN FOR LONG TERM RELIABILITY.
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Creator
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Kutty, Karan, Yuan, Jiann-Shiun, University of Central Florida
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Abstract / Description
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This study investigated the Class-E power amplifier operating at 5.2 GHz. Since the operation of this amplifier applies a lot of stress on the switching transistor, a cascode topology was applied in order to reduce the drain-source voltage stress. Such an amplifier was designed and optimized in order to improve stability, power added efficiency, and matching. A layout for the said design was then created to be fabrication-ready using the TSMC 0.18 um technology. Post-layout simulations were...
Show moreThis study investigated the Class-E power amplifier operating at 5.2 GHz. Since the operation of this amplifier applies a lot of stress on the switching transistor, a cascode topology was applied in order to reduce the drain-source voltage stress. Such an amplifier was designed and optimized in order to improve stability, power added efficiency, and matching. A layout for the said design was then created to be fabrication-ready using the TSMC 0.18 um technology. Post-layout simulations were performed in order to realize a more realistic circuit performance with the layout design in mind. Long-term stress effects, such as oxide breakdown, on the key transistors were modeled and simulated in order to achieve an understanding of how leakage currents affect the overall circuit performance. Simulated results were compared and contrasted against theoretical understanding using derived equations. Recommendations for future advancements were made for modification and optimization of the circuit by the application of other stress reduction strategies, variation in the class-E topology, and improvement of the driver stage.
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Date Issued
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2010
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Identifier
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CFE0003360, ucf:48477
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Format
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Document (PDF)
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PURL
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http://purl.flvc.org/ucf/fd/CFE0003360
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Title
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Quantitative Line Assignment in Optical Emission Spectroscopy.
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Creator
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Chappell, Jessica, Baudelet, Matthieu, Hernandez, Florencio, Campiglia, Andres, Ni, Liqiang, Sigman, Michael, University of Central Florida
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Abstract / Description
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Quantitative elemental analysis using Optical Emission Spectroscopy (OES) starts with a high level of confidence in spectral line assignment from reference databases. Spectral interferences caused by instrumental and line broadening decrease the resolution of OES spectra creating uncertainty in the elemental profile of a sample for the first time. An approach has been developed to quantify spectral interferences for individual line assignment in OES. The algorithm calculates a statistical...
Show moreQuantitative elemental analysis using Optical Emission Spectroscopy (OES) starts with a high level of confidence in spectral line assignment from reference databases. Spectral interferences caused by instrumental and line broadening decrease the resolution of OES spectra creating uncertainty in the elemental profile of a sample for the first time. An approach has been developed to quantify spectral interferences for individual line assignment in OES. The algorithm calculates a statistical interference factor (SIF) that combines a physical understanding of plasma emission with a Bayesian analysis of the OES spectrum. It can be used on a single optical spectrum and still address individual lines. Contrary to current methods, quantification of the uncertainty in elemental profiles of OES, leads to more accurate results, higher reliability and validation of the method. The SIF algorithm was evaluated for Laser-Induced Breakdown Spectroscopy (LIBS) on samples with increasing complexity: from silicon to nickel spiked alumina to NIST standards (600 glass series and nickel-chromium alloy). The influence of the user's knowledge of the sample composition was studied and showed that for the majority of spectral lines this information is not changing the line assignment for simple compositions. Nonetheless, the amount of interference could change with this information, as expected. Variance of the SIF results for NIST glass standard was evaluated by the chi-square hypothesis test of variance showing that the results of the SIF algorithm are very reproducible.
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Date Issued
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2018
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Identifier
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CFE0007564, ucf:52575
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Format
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Document (PDF)
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PURL
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http://purl.flvc.org/ucf/fd/CFE0007564
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Title
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Development of laser spectroscopy for elemental and molecular analysis.
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Creator
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Liu, Yuan, Richardson, Martin, Vanstryland, Eric, Bass, Michael, Sigman, Michael, University of Central Florida
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Abstract / Description
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Laser-Induced Breakdown Spectroscopy (LIBS) and Raman spectroscopy are still growing analytical and sensing spectroscopic techniques. They significantly reduce the time and labor cost in analysis with simplified instrumentation, and lead to minimal or no sample damage. In this dissertation, fundamental studies to improve LIBS analytical performance were performed and its fusion with Raman into one single sensor was explored.On the fundamental side, Thomson scattering was reported for the...
Show moreLaser-Induced Breakdown Spectroscopy (LIBS) and Raman spectroscopy are still growing analytical and sensing spectroscopic techniques. They significantly reduce the time and labor cost in analysis with simplified instrumentation, and lead to minimal or no sample damage. In this dissertation, fundamental studies to improve LIBS analytical performance were performed and its fusion with Raman into one single sensor was explored.On the fundamental side, Thomson scattering was reported for the first time to simultaneously measure the electron density and temperature of laser plasmas from a solid aluminum target at atmospheric pressure. Comparison between electron and excitation temperatures brought insights into the verification of local thermodynamic equilibrium condition in laser plasmas.To enhance LIBS emission, Microwave-Assisted LIBS (MA-LIBS) was developed and characterized. In MA-LIBS, a microwave field extends the emission lifetime of the plasma and stronger time integrated signal is obtained. Experimental results showed sensitivity improvement (more than 20-fold) and extension of the analytical range (down to a few tens of ppm) for the detection of copper traces in soil samples. Finally, laser spectroscopy systems that can perform both LIBS and Raman analysis were developed. Such systems provide two types of complimentary information (-) elemental composition from LIBS and structural information from Raman. Two novel approaches were reported for the first time for LIBS-Raman sensor fusion: (i) an Ultra-Violet system which combines Resonant Raman signal enhancement and high ablation efficiency from UV radiation, and (ii) a Ti:Sapphire laser based NIR system which reduces the fluorescence interference in Raman and takes advantage of femtosecond ablation for LIBS.
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Date Issued
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2013
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Identifier
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CFE0005105, ucf:50729
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Format
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Document (PDF)
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PURL
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http://purl.flvc.org/ucf/fd/CFE0005105
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Title
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LASER INDUCED BREAKDOWN SPECTROSCOPY FOR DETECTION OF ORGANIC RESIDUES: IMPACT OF AMBIENT ATMOSPHERE AND LASER PARAMETERS.
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Creator
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Brown, Christopher, Richardson, Martin, University of Central Florida
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Abstract / Description
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Laser Induced Breakdown Spectroscopy (LIBS) is showing great potential as an atomic analytical technique. With its ability to rapidly analyze all forms of matter, with little-to-no sample preparation, LIBS has many advantages over conventional atomic emission spectroscopy techniques. With the maturation of the technologies that make LIBS possible, there has been a growing movement to implement LIBS in portable analyzers for field applications. In particular, LIBS has long been considered the...
Show moreLaser Induced Breakdown Spectroscopy (LIBS) is showing great potential as an atomic analytical technique. With its ability to rapidly analyze all forms of matter, with little-to-no sample preparation, LIBS has many advantages over conventional atomic emission spectroscopy techniques. With the maturation of the technologies that make LIBS possible, there has been a growing movement to implement LIBS in portable analyzers for field applications. In particular, LIBS has long been considered the front-runner in the drive for stand-off detection of trace deposits of explosives. Thus there is a need for a better understanding of the relevant processes that are responsible for the LIBS signature and their relationships to the different system parameters that are helping to improve LIBS as a sensing technology. This study explores the use of LIBS as a method to detect random trace amounts of specific organic materials deposited on organic or non-metallic surfaces. This requirement forces the limitation of single-shot signal analysis. This study is both experimental and theoretical, with a sizeable component addressing data analysis using principal components analysis to reduce the dimensionality of the data, and quadratic discriminant analysis to classify the data. In addition, the alternative approach of 'target factor analysis' was employed to improve detection of organic residues on organic substrates. Finally, a new method of characterizing the laser-induced plasma of organics, which should lead to improved data collection and analysis, is introduced. The comparison between modeled and experimental measurements of plasma temperatures and electronic density is discussed in order to improve the present models of low-temperature laser induced plasmas.
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Date Issued
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2011
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Identifier
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CFE0003708, ucf:48843
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Format
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Document (PDF)
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PURL
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http://purl.flvc.org/ucf/fd/CFE0003708