Contribution à l'étude du comportement thermique de la batterie lithium-ion pour véhicules électriques et hybrides / Contribution to thermal behaviour study of lithium-ion battery for electric and hybrid electric vehicle

Che Daud, Zul Hilmi

17 December 2014

Les principaux objectifs de cette étude est de fournir les informations essentielles sur le comportement thermique des cellules de batterie pour une application automobile, en particulier pour les véhicules électriques et hybrides. Cette application est notre cadre de travail expérimental afin de développer un modèle électro-thermique 3D efficace pour les cellules lithium-ion et du pack batterie. L'étude expérimentale se concentre sur la distribution de température en différents points de la surface de la cellule, de l'impact de différents débits constants, et également l'importance du système de refroidissement sur le comportement en température de la batterie. Cette thèse met en évidence le comportement de température de la cellule dans des conditions de décharge agressive et de l'impact de l'empilement de plusieurs cellules à l'intérieur de la batterie. Une étude de cas sur le comportement thermique de la cellule dans une application véhicule électrique hybride série est proposée pour compléter les cycles de conduite en utilisant différentes stratégies de refroidissement. En outre, l'étude expérimentale est étendue à la caractéristique du comportement de refroidissement par flux d'air à l'intérieur de la batterie, en utilisant le système d'image de particules (PIV). Le modèle électro-thermique CFD 3D est développé sous un logiciel Open Source OpenFOAM. L'objectif principal est d'obtenir un modèle relativement simple mais précis avec un temps de calcul raisonnable. Le modèle proposé, estime la production de chaleur, à partir du courant de la batterie et la résistance interne en fonction de la température, le transfert de chaleur par conduction, convection forcée et rayonnement. / The main objectives of this study are to provide the essential information on the thermal behaviour of the battery cells for automotive purpose especially for EVs and HEVs through experimental work in order to develop an effective 3D electro-thermal model for lithium ion battery cells and pack. The experimental study is focusing on the distribution of temperature at various points of the battery cell surface, impact of different constant discharge rates, and also the importance of cooling system on the battery temperature behaviour. This thesis highlights the battery cell temperature under abuse discharge condition and the impact of stacking the battery cells inside the battery pack. Impact of different temperature and SOC on the battery cell internal resistance and a case study on the battery cell thermal behaviour used in a series HEV to complete driving cycles using different cooling strategies are also studied. Furthermore, the experimental study is extended to the characteristic of the cooling air flow behaviour inside the battery pack, using particulate image velocimetry (PIV) system. The 3D electro-thermal CFD model is implemented in a free, open source CFD software package called OpenFOAM. The target is to have a relatively simple but accurate model with reasonable computation time. This proposed model considers the heat generation from battery current and internal resistance as a function of temperature, heat transfer through conduction, forced convection and radiation.

Comportement thermique

Batterie lithium-ion

Étude expérimental

Véhicules électriques et hybrides

Modèle électro-thermique

Modèle CFD 3D

Thermal behaviour

Lithium-ion battery

Experimental study

Particle image velocimetry (PIV)

Electric and hybrid electric vehicles

Electro-thermal model

3D CFD model

620.1

Integrated Gas Sensor - Studies On Sensing Film Deposition, Microheater Design And Fabrication, Interface Electronics Design And Testing

Velmathi, G

03 1900

Recently, there has been an increasing interest in the electronics world for those aspects related to semiconducting gas sensor (SGS) materials. In view of the increasingly strict legal limits for pollutant gas emissions, there is a great interest in developing high performance gas sensors for applications such as controlling air pollution and exhaust gases in automotive industry. In this way, semiconductor gas sensors offer good advantages with respect to other gas sensor devices, due to their simple implementation, low cost and good stability and sensitivity. The first part of the thesis is dedicated to the synthesis, film structural and sensitivity study of the Tin Oxide film deposited by RF sputtering, doped with noble metal Palladium (Pd). Effects on the Gas Sensitivity due to the deposition parameters like thickness of the film, Substrate temperature, Ar /O2 ratio of the sputtering environment, annealing temperature and duration and doping metal weight % into the Tin Oxide films are studied and the results are shown in detail. The sensitivity and selectivity of the gas sensing film is decided by the operating temperature i.e. the temperature of the gas sensing film while it is in the target gas ambience, Microheaters happen to be the very important component in the gas sensor especially with wide band gap semiconducting metal oxides films such as tin oxide, gallium oxide or indium oxides. Other than gas sensing microheater also finds applications in many areas like thermal dip pen nanolithography, polymerase chain reaction (PCR), fluid pumping with bubbles, in vitro fertilization etc. So in this report due importance was given for the design and fabrication of the microheater. Microheaters are the most power consuming element of the integrated Gas sensors. This is also an important reason for the extensive microheater work in this research. Six different heater patterns were simulated by considering low power and temperature uniformity as an important goals. Among them the best three patterns named Double spiral, “Fan” Shape and “S” shape were chosen for fabrication and both thermal and electrical characterization results of them were presented in detail in the Microheater section of the thesis. It is believed that the intelligent design and integration of the electronic circuitry (for drive, signal conditioning/compensation, and read-out) with the gas sensing element can mitigate some of the significant issues inherent in solid-state gas sensors, such as strong temperature and humidity dependence, signal drift, aging, poisoning, and weak selectivity. The sensitivity of the gas sensors which has been indicated as the dynamic change of resistance in wide range should be read out properly. Towards this aim a low cast high efficient readout circuit is designed and implemented. Temperature monitoring and controlling is a key phenomenon in the metal Oxide based gas sensors since the selectivity mainly depends on the operating temperature of the sensing film. So focus was also shown on the design and implementation of the temperature monitoring and control unit, which been presented in the last part of this thesis.

Gas Sensors

Gas Sensing Films

Gas Sensing Film Deposition

Microheaters - Design and Fabrication

Electro-Thermal Simulation

Tin Oxide Films

Thin Film Gas Sensors

Interface Electronic Circuits

Microheaters Design

SnO2 Sensors

Gas Sensor Applications

Gas Sensing

Instrumentation

Silizium- und SiC-Leistungsdioden unter besonderer Berücksichtigung von elektrisch-thermischen Kopplungseffekten und nichtlinearer Dynamik

Felsl, Hans Peter

28 July 2009

Diese Arbeit befasst sich mit Hochleistungsdioden aus den Halbleitermaterialen Silizium und Siliziumkarbid. Analysiert werden die statischen und dynamischen Schalteigenschaften. Bei den SiC-Bauelementen handelt es sich um unipolare Schottky-Dioden und bei den Silizium-Dioden um bipolare pin-Dioden. Bei den SiC-Schottky-Dioden liegt der Schwerpunkt auf der Analyse des statischen Durchbruchverhaltens von Randstrukturen und auf der Untersuchung der Selbsterwärmung bei Einzel- und Mehrpulsbelastung. Bei den bipolaren Silizium-Dioden wird das Durchbruchverhalten bei niedrigen und hohen Stromdichten untersucht. Aus den Sperrcharakteristiken, die positiv und negativ differentielle Widerstandsäste aufweisen, lassen sich Schlussfolgerungen auf das dynamische Verhalten ziehen. Das Abschaltverhalten (reverse recovery) der mit Plasma überschwemmten Bauelemente wird zuerst im Hinblick auf den Einfluss von Strukturparametern untersucht, um die prinzipiellen Einflussgrößen zu erläutern. Dann folgen die Ergebnisse zur Filamentbildung, die bei den hohen Belastungen der Bauelemente während des Kommutierungsprozesses auftreten können. Die auftretenden Filamentstrukturen werden analysiert und - soweit möglich - Einflussgrößen herausgearbeitet. Schließlich wird noch auf den Einfluss von Randstrukturen auf das Filamentierungsverhalten, die als Inhomogenität in jedem Bauelement vorhanden sind, eingegangen.

info:eu-repo/classification/ddc/620

ddc:620

Diode

Leistungselektronik

Schaltverhalten

Schottky-Diode

Silicium

Siliciumcarbid

Abschaltverhalten

Filamentierung

Kommutierungsverhalten

Reverse Recovery

Stromfilament

Stromfilamentierung

Wärmekapazität

Wärmeleitung

bipolar diode

current filament

electro-thermal behavior

elektrothermisches Verhalten

negativ differential resistance

nichtlineare Dynamik

non linear dynamics

pin Diode

pin diode

schottky diode

silicon carbide

silicon diode

unipolar diode

Ruggedness of 1200V SiC Schottky and MPS Diodes

Fichtner, Susanne

14 December 2018

Eine wichtige Eigenschaft von Leistungsdioden ist ihre Stoßstromrobustheit, also die Fähigkeit, einem kurzeitigen hohen Strom standzuhalten. Bei Dioden aus SiC wird dabei häufig auf die MPS-Struktur zurückgegriffen. In dieser Arbeit wird das Stoßstromverhalten von neuen 1200V-SiC-MPS-Dioden von Infineon untersucht. Dabei wird gemessen, welchem Strom die Dioden bei einem Halbsinus-Puls von 10ms standhalten. Das Ergebnis wird mit der Robustheit herkömmlicher SiC-Schottky-Dioden verglichen. Die Stoßstromrobustheit bei Parallelschaltung wird untersucht. Mittels elektro-thermischer Simulationen werden Möglichkeiten zur Verbesserung der Stoßstromrobustheit der Dioden erörtert. Hierbei wird die Schichtdicke erhöht und Kupfer statt Aluminium als Anodenmetallisierung angenommen. Des Weiteren wird das Simulationsmodell hinsichtlich der Lotschicht und eines reduzierten SiC-Substrats variiert. Die MPS-Dioden weisen bei hohem Strom einen negativen differentiellen Widerstand auf, hervorgerufen durch die Injektion von Minoritätsladungsträgern aus den p-dotierten Gebieten. Die Aktivierung der Injektion von Minoritätsladungsträgern in Abhängigkeit der Größe der p-dotierten Gebiete wird ebenfalls mittels Simulationen untersucht. Ein Vergleich verschiedener Caughey-Thomas-Parameter zur Modellierung der Ladungsträgermobilität in FEM-Bauelementsimulatoren wird durchgeführt. Das Ausschaltverhalten der MPS-Dioden wird unter verschiedenen Bedingungen gemessen. Dazu zählen das Abschalten unter Anwendungsbedingungen, das Abschalten unter Überlast von bis zum fünfzehnfachen Nennstrom, das Abschalten mit hohen Strom- und Spannungssteilheiten und das Abschalten in Parallelschaltung und mit zusätzlicher parasitärer Induktivität. Die Untersuchungen zeigen eine hohe Robustheit der neuen 1200V-SiC-MPS-Dioden. / The surge current ruggedness is an import property of power diodes. In case of SiC diodes this is realized by a Merged-pin-Schottky (MPS) structure. In this thesis the surge current ruggedness of novel 1200V SiC MPS diodes from Infineon is investigated. The maximum current during a half sine surge current pulse of 10ms is determined in measurements for various diodes and compared to the surge current ruggedness of conventional Schottky diodes. Furthermore, the surge current ruggedness in parallel arrangement is measured. By the means of electro-thermal simulations options to improve the surge current ruggedness are investigated. The simulation model is varied concerning the diodes anode metalization layer thickness and material. The layer thickness is increased and the typical aluminum is replaced by copper. Additionally, the influence of the silicon carbide substrate thickness and the solder layer thickness and material on the surge current ruggedness is simulated. The MPS diodes possess a negative differential resistance at high currents caused by the injection of minority carriers by the p-doped regions. The injection of minority carriers in dependence of the size of the p-regions is also examined in simulations. Furthermore, different parameter sets of the the Caughey-Thomas formula to describe the carrier mobility are compared. The turn-off behavior of the diodes is measured under different conditions such as the turn-off from fifteen times the rated current, the turn-off with high current and voltage slopes and the turn-off in parallel arrangement and with additional inductance. The investigation show a high robustness of the novel 1200V SiC MPS diodes.

info:eu-repo/classification/ddc/621.3

ddc:621.3

STRUCTURAL AND MATERIAL INNOVATIONS FOR HIGH PERFORMANCE BETA-GALLIUM OXIDE NANO-MEMBRANE FETS

Jinhyun Noh (10225202)

12 March 2021

<p>Beta-gallium oxide (<i>β</i>-Ga₂O₃) is an emerging wide bandgap semiconductor for next generation power devices which offers the potential to replace GaN and SiC. It has an ultra-wide bandgap (UWBG) of 4.8 eV and a corresponding <i>E</i>_brof 8 MV/cm. <i>β</i>-Ga₂O₃also possesses a decent intrinsic electron mobility limit of 250 cm²/V<i>·</i>s, yielding high Baliga’s figure of merit of 3444. In addition, the large bandgap of <i>β</i>-Ga₂O₃gives stability in harsh environment operation at high temperatures. </p> <p>Although low-cost large-size <i>β</i>-Ga₂O₃native bulk substrates can be realized by melt growth methods, the unique property that (100) surface of <i>β</i>-Ga₂O₃has a large lattice constant of 12.23 Å allows it to be cleaved easily into thin and long nano-membranes. Therefore, <i>β</i>-Ga₂O₃FETs on foreign substrates by transferring can be fabricated and investigated before <i>β</i>-Ga₂O₃epitaxy technology becomes mature and economical viable. Moreover, integrating <i>β</i>-Ga₂O₃on high thermal conductivity materials has an advantage in terms of suppressing self-heating effects. </p><p>In this dissertation, structural and material innovations to overcome and improve critical challenges are summarized as follows: 1) Top-gate nano-membrane <i>β</i>-Ga₂O₃FETs on a high thermal conductivity diamond substrate with record high maximum drain current densities are demonstrated. The reduced self-heating effect due to high thermal conductivity of the substrate was verified by thermoreflectance measurement. 2) Local electro-thermal effect by electrical bias was applied to enhance the electrical performance of devices and improvements of electrical properties were shown after the annealing. 3) Thin thermal bridge materials such as HfO₂and ZrO₂were inserted between <i>β</i>-Ga₂O₃and a sapphire substrate to reduce self heating effects without using a diamond substrate. The improved thermal performance of the device was analyzed by phonon density of states plots of <i>β</i>-Ga₂O₃and the thin film materials. 4) Nano-membrane tri-gate <i>β</i>-Ga₂O₃FETs on SiO₂/Si substrate fabricated via exfoliation have been demonstrated for the first time. 5) Using the robustness of <i>β</i>-Ga₂O₃in harsh environments, <i>β</i>-Ga₂O₃ferroelectric FETs operating as synaptic devices up to 400 °C were demonstrated. The result offers the potential to use the novel device for ultra-wide bandgap logic applications, specifically neuromorphic computing exposed to harsh environments.<br></p>

Compound Semiconductors

Beta-gallium-oxide

Gallium oxide

Nano-membrane

Thermal conductivity

Self-heating effect

Thermal annealing

Electro-thermal effect

Thermal boundary conductance

Interfacial conductance

Phonon density of states

FinFET

HZO

Ferroelectric

Synaptic device

FeFET

High temperature

On-chip learning

Electro-thermal characterization, TCAD simulations and compact modeling of advanced SiGe HBTs at device and circuit level / Caractérisation électrothermique, simulations TCAD et modélisation compacte de transistors HBT en SiGe au niveau composant et circuit

D'Esposito, Rosario

29 September 2016

Ce travail de thèse présente une étude concernant la caractérisation des effets électrothermiques dans les transistors bipolaires à hétérojonction (HBT) en SiGe. Lors de ces travaux, deux procédés technologiques BiCMOS à l’état de l’art ont été analysés: le B11HFC de Infineon Technologies (130nm) et le B55 de STMicroelectronics (55nm).Des structures de test dédiées ont étés conçues, pour évaluer l’impact électrothermique du back end of line (BEOL) de composants ayant une architecture à un ou plusieurs doigts d’émetteur. Une caractérisation complète a été effectuée en régime continu et en mode alternatif en petit et en grand signal. De plus, une extraction des paramètres thermiques statiques et dynamiques a été réalisée et présentée pour les structures de test proposées. Il est démontré que les figures de mérite DC et RF s’améliorent sensiblement en positionnant des couches de métal sur le transistor, dessinées de manière innovante et ayant pour fonction de guider le flux thermique vers l’extérieur. L’impact thermique du BEOL a été modélisé et vérifié expérimentalement dans le domaine temporel et fréquentiel et aussi grâce à des simulations 3D par éléments finis. Il est à noter que l’effet du profil de dopage sur la conductivité thermique est analysé et pris en compte.Des topologies de transistor innovantes ont étés conçues, permettant une amélioration des spécifications de l’aire de sécurité de fonctionnement, grâce à un dessin innovant de la surface d’émetteur et du deep trench (DTI).Un modèle compact est proposé pour simuler les effets de couplage thermique en dynamique entre les émetteurs des HBT multi-doigts; ensuite le modèle est validé avec de mesures dédiées et des simulations TCAD.Des circuits de test ont étés conçus et mesurés, pour vérifier la précision des modèles compacts utilisés dans les simulateurs de circuits; de plus, l’impact du couplage thermique entre les transistors sur les performances des circuits a été évalué et modélisé. Finalement, l’impact du dissipateur thermique positionné sur le transistor a été étudié au niveau circuit, montrant un réel intérêt de cette approche. / This work is focused on the characterization of electro-thermal effects in advanced SiGe hetero-junction bipolar transistors (HBTs); two state of the art BiCMOS processes have been analyzed: the B11HFC from Infineon Technologies (130nm) and the B55 from STMicroelectronics (55nm).Special test structures have been designed, in order to evaluate the overall electro-thermal impact of the back end of line (BEOL) in single finger and multi-finger components. A complete DC and RF electrical characterization at small and large signal, as well as the extraction of the device static and dynamic thermal parameters are performed on the proposed test structures, showing a sensible improvement of the DC and RF figures of merit when metal dummies are added upon the transistor. The thermal impact of the BEOL has been modeled and experimentally verified in the time and frequency domain and by means of 3D TCAD simulations, in which the effect of the doping profile on the thermal conductivity is analyzed and taken into account.Innovative multi-finger transistor topologies are designed, which allow an improvement of the SOA specifications, thanks to a careful design of the drawn emitter area and of the deep trench isolation (DTI) enclosed area.A compact thermal model is proposed for taking into account the mutual thermal coupling between the emitter stripes of multi-finger HBTs in dynamic operation and is validated upon dedicated pulsed measurements and TCAD simulations.Specially designed circuit blocks have been realized and measured, in order to verify the accuracy of device compact models in electrical circuit simulators; moreover the impact on the circuit performances of mutual thermal coupling among neighboring transistors and the presence of BEOL metal dummies is evaluated and modeled.

Effets électrothermiques

Résistance thermique

Capacitance thermique

Impédance thermique

Back end of line (BEOL)

Layout des doigts d’émetteur

Spécifications SOA

Couplage thermique intra-device

Simulations thermiques TCAD

Impact thermique du profile de dopage

Mesures pulsées

Caractérisation load-pull

Modèle HiCuM

Electro-thermal effects

Thermal resistance

Thermal capacitance

Thermal impedance

Back end of line (BEOL)

Emitter-finger layout

SOA specifications

Intra device mutual thermal coupling

Circuits for model verification

Device to circuit interactions

Thermal TCAD simulations

Doping profile thermal impact,

Semiconductor device characterization

HiCuM model

Semiconductor device modeling