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A simulation study on the performance improvement of CMOS devices using alternative gate electrode structuresKomaragiri, Rama Subrahmanyam Unknown Date (has links)
Techn. Univ., Diss., 2006--Darmstadt
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On the stability of a variety of organic photovoltaic devices by IPCE and in situ IPCE analyses – the ISOS-3 inter-laboratory collaborationTeran-Escobar, Gerardo, Tanenbaum, David M., Voroshazi, Eszter, Hermenau, Martin, Norrman, Kion, Lloyd, Matthew T., Galagan, Yulia, Zimmermann, Birger, Hösel, Markus, Dam, Henrik F., Jørgensen, Mikkel, Gevorgyan, Suren, Kudret, Suleyman, Maes, Wouter, Lutsen, Laurence, Vanderzande, Dirk, Würfel, Uli, Andriessen, Ronn, Rösch, Roland, Hoppe, Harald, Rivaton, Agnès, Uzunoğlu, Gülşah Y., Germack, David, Andreasen, Birgitta, Madsen, Morten V., Bundgaard, Eva, Krebs, Frederik C., Lira-Cantu, Monica 07 April 2014 (has links) (PDF)
This work is part of the inter-laboratory collaboration to study the stability of seven distinct sets of state-of-the-art organic photovoltaic (OPV) devices prepared by leading research laboratories. All devices have been shipped to and degraded at RISØ-DTU up to 1830 hours in accordance with established ISOS-3 protocols under defined illumination conditions. In this work, we apply the Incident Photon-to-Electron Conversion Efficiency (IPCE) and the in situ IPCE techniques to determine the relation between solar cell performance and solar cell stability. Different ageing conditions were considered: accelerated full sun simulation, low level indoor fluorescent lighting and dark storage. The devices were also monitored under conditions of ambient and inert (N2) atmospheres, which allows for the identification of the solar cell materials more susceptible to degradation by ambient air (oxygen and moisture). The different OPVs configurations permitted the study of the intrinsic stability of the devices depending on: two different ITO-replacement alternatives, two different hole extraction layers (PEDOT:PSS and MoO3), and two different P3HT-based polymers. The response of un-encapsulated devices to ambient atmosphere offered insight into the importance of moisture in solar cell performance. Our results demonstrate that the IPCE and the in situ IPCE techniques are valuable analytical methods to understand device degradation and solar cell lifetime. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.
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On the stability of a variety of organic photovoltaic devices by IPCE and in situ IPCE analyses – the ISOS-3 inter-laboratory collaborationTeran-Escobar, Gerardo, Tanenbaum, David M., Voroshazi, Eszter, Hermenau, Martin, Norrman, Kion, Lloyd, Matthew T., Galagan, Yulia, Zimmermann, Birger, Hösel, Markus, Dam, Henrik F., Jørgensen, Mikkel, Gevorgyan, Suren, Kudret, Suleyman, Maes, Wouter, Lutsen, Laurence, Vanderzande, Dirk, Würfel, Uli, Andriessen, Ronn, Rösch, Roland, Hoppe, Harald, Rivaton, Agnès, Uzunoğlu, Gülşah Y., Germack, David, Andreasen, Birgitta, Madsen, Morten V., Bundgaard, Eva, Krebs, Frederik C., Lira-Cantu, Monica January 2012 (has links)
This work is part of the inter-laboratory collaboration to study the stability of seven distinct sets of state-of-the-art organic photovoltaic (OPV) devices prepared by leading research laboratories. All devices have been shipped to and degraded at RISØ-DTU up to 1830 hours in accordance with established ISOS-3 protocols under defined illumination conditions. In this work, we apply the Incident Photon-to-Electron Conversion Efficiency (IPCE) and the in situ IPCE techniques to determine the relation between solar cell performance and solar cell stability. Different ageing conditions were considered: accelerated full sun simulation, low level indoor fluorescent lighting and dark storage. The devices were also monitored under conditions of ambient and inert (N2) atmospheres, which allows for the identification of the solar cell materials more susceptible to degradation by ambient air (oxygen and moisture). The different OPVs configurations permitted the study of the intrinsic stability of the devices depending on: two different ITO-replacement alternatives, two different hole extraction layers (PEDOT:PSS and MoO3), and two different P3HT-based polymers. The response of un-encapsulated devices to ambient atmosphere offered insight into the importance of moisture in solar cell performance. Our results demonstrate that the IPCE and the in situ IPCE techniques are valuable analytical methods to understand device degradation and solar cell lifetime. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.
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Theoretical Investigation of High-k Gate Stacks in nano-MOSFETsNadimi, Ebrahim 19 July 2022 (has links)
Diese Arbeit beschäftigt sich mit der „First-Principles“ atomskaligen Modellierung der HfO2-basierten high-k-Gate-Isolatorschichten der Metalloxid-Halbleiter-Feldeffekttransistoren. Die theoretischen Untersuchungen basieren auf Dichtefunktionaltheorie und Nichtgleichgewicht-Greensche-Funktion-Formalismen. Eine der wichtigsten Eigenschaften eines Gate-Isolators ist der Wert seiner Bandlücke. Die Bandlücke eines gemischten Festkörpers aus SiO2 und ZrO2 oder HfO2 wird auf der Grundlage der „Generalized Quasi-Chemical“ Approximation in Kombination mit dem „Cluster Expansion“ Ansatz berechnet. Zu diesem Zweck wurde Dichtefunktionaltheorie für die Berechnung der Eigenschaften verschiedener Konfigurationen möglicher Elementarzellen durchgeführt. Es wurde ein fast linearer Verlauf für die Bandlücke eines aus SiO2 und HfO2 gemischten Festkörpers berechnet. Im Vergleich zu dem üblichen SiO2 Gate-Isolator, haben die high-k-Gate-Isolatoren eine höhere Defektdichte, die hauptsächlich aus Sauerstoffleerstellen bestehen. Dies führt zu mehreren Problemen, wie zum Beispiel höherer Leckstrom, Schwellenspannungsverschiebung und Degradation des Gateoxids. Daher wurde eine umfassende Untersuchung der verschiedenen Eigenschaften von Sauerstofffehlstellen in HfO2 durchgeführt, indem wichtige Parameter wie zum Beispiel die Formationsenergien und die Lage der Defektniveaus in der Bandlücke berechnet wurden. Es wurde durch die theoretischen Berechnungen gezeigt, dass die schädlichen Auswirkungen von Sauerstofffehlstellen durch die Einführung von Lanthan-Atomen in dem HfO2 Kristallgitter teilweise zu verringern sind. Energetisch gesehen bevorzugen die Lanthan-Atome die Hf-Gitterplätze in der Nachbarschaft einer Sauerstofffehlstelle und führen dadurch zu der Passivierung durch Sauerstoffleerstelle induzierten Defektniveaus. Die high-k-Isolatorschicht in den heutigen Transistoren besteht aus drei Schichten: einem Metallgate, einer HfO2-Schicht als Haupt-Gate-Isolator und einer sehr dünnen SiO2 Übergangsschicht zwischen Gateoxid und Si. Die Einführung eines Metallgates führt zu einigen Problemen bei der Einstellung einer geeigneten Schwellenspannung in den Transistoren. Theoretische Berechnungen in einer komplexen Modellstruktur von der Si/SiO2/HfO2-Grenzfläche zeigen, dass die dotierten Lanthan-Atome energetisch die SiO2/HfO2-Grenzfläche bevorzugen, was wiederum ein Dipolmoment an der Grenzfläche erzeugt. Dieses Dipolmoment kann verwendet werden, um die richtige Schwellenspannung wieder einzustellen. Schließlich wird in den experimentellen Messungen festgestelltes progressives Degradationsverhalten von high-k-Gate-Isolatoren mit einem theoretischen Modell erklärt. Dieses Modell basiert auf ab-initio-Berechnungen und zeigt, wie die Erzeugung geladener Sauerstoffleerstellen und deren Migration unter der angelegten Gatespannung zu einer progressiven Erhöhung des Leckstroms und folglich zu einer Degradation der Isolatorschicht führt.:List of Figures 7
List of Tables 9
List of Symbols 10
List of Abbreviations 11
Chapter 1: Introduction 12
Chapter 2: Theory of Atomic-Scale First-Principles Calculations 15
2.1 Theoretical methods 15
2.2 Density functional theory 17
2.3 Non-equilibrium Green’s function formalism 23
Chapter 3: Calculations for Bulk High-k Materials 27
3.1 Bulk high-k materials 27
3.2 Crystalline insulators 27
3.3 Solid solutions 29
3.3.1 Cluster expansion approach 30
3.3.2 Band gap and bowing parameter 33
3.3.3 Calculation of internal stress 40
3.4 Leakage current 41
Chapter 4: Defects in Bulk High-k Materials 43
4.1 Defects in high-k gate dielectrics 43
4.2 Oxygen vacancies in monoclinic HfO2 44
4.2.1 Neutral oxygen vacancies 44
4.2.2 Charged oxygen vacancies 46
4.3 Hybrid functional 50
4.4 Double oxygen vacancies 56
4.5 Interaction of oxygen vacancies with La-doping 61
4.5.1 La doping in m-HfO2 61
4.5.2 Complex LaHfVO defects 64
Chapter 5: Interface Properties of High-k Gate Stack 72
5.1 high-k gate-stack 72
5.1.1 Atomic-scale model structure for a high-k gate-stack 72
5.1.2 Electronic structure 74
5.1.3 Leakage current 76
5.2 Band offset 80
5.3 Threshold voltage engineering with La doping 84
Chapter 6: Degradation of the High-k Gate Stack 90
6.1 Reliability issues in high-k gate-stack 90
6.2 Calculations and experimental methods 91
6.3 Leakage current 92
6.4 Defect generation 100
6.5 Explaining progressive SILC in high-k dielectrics 102
Chapter 7: Conclusions 104
Bibliography 106
Selbständigkeitserklärung 119
Danksagung 120
Lebenslauf 121
Veröffentlichungen 122 / This thesis deals with the first-principles atomic-scale modeling of the HfO2-based high-k gate-insulator layer of the metal-oxide-semiconductor field-effect transistors. The theoretical investigations are based on density functional theory and non-equilibrium Green's function formalisms. One of the important properties of the gate insulator is the value of its band gap. The band gap of amorphous solid mixtures of SiO2 and ZrO2 or HfO2 is calculated based on generalized quasi-chemical approximation combined with a cluster expansion approach, by performing density functional calculations on different configurations of possible unit cells. An almost linear variation of the band gap is obtained for solid mixtures of SiO2 and HfO2. One drawback of the high-k gate-insulator, comparing to the standard SiO2, is high density of defects, particularly oxygen vacancies, which leads to several problems such as enhancement of the leakage current, threshold voltage instability, and degradation of the gate-oxide. A comprehensive investigation of different properties of oxygen vacancies in HfO2 is conducted by the calculation of formation energies and induced trap levels. It is shown based on theoretical calculations that the harmful effects of oxygen vacancies can be partially healed by introducing lanthanum atoms into the defected HfO2 crystal. Lanthanum atoms energetically prefer to occupy Hf lattice sites close to the oxygen vacancies and passivate the induced defect levels. The state-of-the-art high-k gate-stacks consist of a metal-gate on a HfO2 layer, as the main part of the gate insulator, and a very thin SiO2 intermediate layer between high-k material and Si. The introduction of a metal-gate raises some problem in the adjustment of an appropriate threshold voltage. Theoretical calculations in a complex model structure of the Si/SiO2/HfO2 interface reveals that the lanthanum atoms energetically prefer to stay at the SiO2/HfO2 interface, which in turn results in a dipole moment. This dipole moment can be employed to adjust the threshold voltage in high-k/metal-gate stacks. Finally, a theoretical model, which can quiet well explain the experimental measurements, is introduced for the progressive degradation of the high-k gate-insulators. This model is based on ab-initio calculations and shows how the generation of charged vacancies and their migration under the applied gate voltage leads to the progressive enhancement of the leakage current and consequently to the degradation of the insulator layer.:List of Figures 7
List of Tables 9
List of Symbols 10
List of Abbreviations 11
Chapter 1: Introduction 12
Chapter 2: Theory of Atomic-Scale First-Principles Calculations 15
2.1 Theoretical methods 15
2.2 Density functional theory 17
2.3 Non-equilibrium Green’s function formalism 23
Chapter 3: Calculations for Bulk High-k Materials 27
3.1 Bulk high-k materials 27
3.2 Crystalline insulators 27
3.3 Solid solutions 29
3.3.1 Cluster expansion approach 30
3.3.2 Band gap and bowing parameter 33
3.3.3 Calculation of internal stress 40
3.4 Leakage current 41
Chapter 4: Defects in Bulk High-k Materials 43
4.1 Defects in high-k gate dielectrics 43
4.2 Oxygen vacancies in monoclinic HfO2 44
4.2.1 Neutral oxygen vacancies 44
4.2.2 Charged oxygen vacancies 46
4.3 Hybrid functional 50
4.4 Double oxygen vacancies 56
4.5 Interaction of oxygen vacancies with La-doping 61
4.5.1 La doping in m-HfO2 61
4.5.2 Complex LaHfVO defects 64
Chapter 5: Interface Properties of High-k Gate Stack 72
5.1 high-k gate-stack 72
5.1.1 Atomic-scale model structure for a high-k gate-stack 72
5.1.2 Electronic structure 74
5.1.3 Leakage current 76
5.2 Band offset 80
5.3 Threshold voltage engineering with La doping 84
Chapter 6: Degradation of the High-k Gate Stack 90
6.1 Reliability issues in high-k gate-stack 90
6.2 Calculations and experimental methods 91
6.3 Leakage current 92
6.4 Defect generation 100
6.5 Explaining progressive SILC in high-k dielectrics 102
Chapter 7: Conclusions 104
Bibliography 106
Selbständigkeitserklärung 119
Danksagung 120
Lebenslauf 121
Veröffentlichungen 122
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