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Out-of-equilibrium electron dynamics of Dirac semimetals and strongly correlated materials / Dynamique hors équilibre des électrons dans les sémimétaux de Dirac et les matériaux fortement corrélésNilforoushan, Niloufar 17 December 2018 (has links)
Les matériaux quantiques ont récemment introduit en physique de la matière condensée pour unifier tous les matériaux dans lesquels les fortes corrélations électroniques gouvernent les propriétés physiques du système (e.g. les isolants de Mott) et les matériaux dont les propriétés électroniques sont déterminées par la géométrie de la fonction d’onde (e.g. matériaux de Dirac). Ces matériaux montrent des propriétés émergentes résultantes de l’intrication de différents degrés de libertés : la charge, le spin et le moment orbital, donnant lieu aux propriétés topologiques des électrons. L’étude de ces interactions et des compétitions entre les degrés de liberté pertinents nécessite l’utilisation de techniques pompe-sonde ultra-rapides. Particulièrement, les pulses laser femtosecondes interagissent uniquement avec les électrons pour les placer dans un état hors-équilibre décrit par des distributions de type non Fermi-Dirac. La dynamique subséquente implique de nombreux processus, avec un temps de relaxation relié aux constantes de couplage. De plus, dans les techniques résolues en temps, la lumière peut agir comme un paramètre externe, différent des paramètres thermodynamiques, pour explorer le diagramme de phase. Cela nous donne l’opportunité de stabiliser de nouveaux états inaccessibles par des chemins thermiques quasi-adiabatiques ou de manipuler les propriétés physiques des systèmes.Dans cette thèse, nous avons réalisé différentes expériences dans le but d’étudier les propriétés à l’équilibre et hors équilibre de deux matériaux corrélés: BaCo₁₋ₓNiₓS₂ et (V₁₋ₓMₓ)₂O₃.La première partie de ce projet a été dédiée principalement à l’étude de BaNiS₂, le précurseur métallique de la transition de Mott dans BaCo₁₋ₓNiₓS₂ . En utilisant l’ARPES, nous avons étudié la structure de bandes électroniques de BaNiS₂ dans toute la zone de Brillouin. L’expérience, combinée avec des calculs théoriques, révèle un nouveau type de cône de Dirac bidimensionel à caractère orbitalaire d et induit par les corrélations. Le croisement des bandes est protégé par les symétries particulières de la structure cristalline. Nous avons aussi mesuré la structure de bandes de l’isolant de Mott BaCoS₂ dans ses phases magnétique et non magnétiques.Dans la seconde partie, nous avons étudié la dynamique électronique hors équilibre de BaNiS₂ et (V₁₋ₓMx)₂O₃. Grâce à des mesures tr-ARPES et tr-Réflectivité, nous avons observé une renormalisation non thermique et ultra-rapide du cône de Dirac dans BaNiS₂. Ce phénomène est purement provoqué par les excitations électroniques et est stabilisé par l’intéraction entre les électrons et les phonons. De plus, en utilisant différentes techniques pompe-sonde (tr-XRD basé sur XFEL et tr-Réflectivité) nous avons aussi exploré des phases hors-équilibre du matériau prototype de Mott-Hubbard (V₁₋ₓMx)₂O₃ appartenant à différentes parties de son diagramme de phase. Nos résultats montrent une phase transitoire non thermique se développant immédiatement après la photoexcitation ultra-rapide et durant quelques picosecondes dans les phases métallique et isolantes. Cette phase transitoire est accompagné par une distorsion structural qui correspond à un durcissement du réseau et est marqué par un “blue shift” du mode phononique A₁g. Nos résultats soulignent l’importance du remplissage des orbitales aussi bien que des effets important des forts couplages électron-réseau sélectifs dans les matériaux fortement corrélés. / Quantum materials is a new term in condensed matter physics that unifies all materials in which strong electronic correlation governs physical properties of the system (e.g. Mott insulators) and materials whose electronic properties are determined by the geometry of the electronic wave function (e.g. Dirac materials). These materials show emergent properties– that is, properties that only appear by intricate interactions among many degrees of freedom, such as charge, spin and orbital, giving rise to topological properties of electrons. The study of these interactions and competitions between the relevant degrees of freedom demands applying ultrafast pump-probe techniques. Particularly, femtosecond laser pulses act only on the electrons and set them to an out-of-equilibrium state inexplicable by the Fermi-Dirac distribution. The ensuing dynamics involves various processes and the rate at which the relaxation occurs is related to the coupling constants. Moreover, in time-resolved pump-probe techniques light can act as an additional external parameter to change of the phase diagram – different from thermodynamic parameters. It gives us the opportunity of stabilizing new states inaccessible by quasi-adiabatic thermal pathways or eventually manipulating the physical properties of the systems.In this thesis, we performed different experiments in order to study the equilibrium and out-of-equilibrium properties of two correlated compounds: BaCo₁₋ₓNiₓS₂ and (V₁₋ₓMₓ)₂O₃.The first part of the project was mainly devoted to the study of BaNiS₂ that is the metallic precursor of the Mott transition in BaCo₁₋ₓNiₓS₂. By applying ARPES, we studied the electronic band structure of BaNiS₂ in its entire Brillouin zone. These results combined with some theoretical calculations give evidence of a novel correlation-induced and two-dimensional Dirac cone with d-orbital character. The band crossing is protected by the specific symmetries of the crystal structure. We also investigated the electronic band structure of the Mott insulator BaCoS₂ in its magnetic and nonmagnetic phases.In the second part, we studied the out-of-equilibrium electron dynamics of BaNiS₂ and (V₁₋ₓMx)₂O₃. By means of tr-ARPES and tr-reflectivity measurements, we observed an ultrafast and non-thermal renormalization of the Dirac cone in BaNiS₂ . This phenomenon is purely provoked by the electronic excitation and is stabilized by the interplay between the electrons and phonons. Moreover, by applying various pump-probe techniques (XFEL-based tr-XRD and tr-Reflectivity) we also explored the out-of-equilibrium phases of the prototype Mott-Hubbard material (V₁₋ₓMx)₂O₃ in different parts of its phase diagram. Our results show a transient non-thermal phase developing immediately after ultrafast photoexcitation and lasting few picoseconds in both metallic and insulating phases. This transient phase is followed by a structural distortion that corresponds to a lattice hardening and is marked by a “blue shift” of the A₁g phonon mode. These results underline the importance of the orbital filling as well as the strong effect of the selective electron-lattice coupling in the strongly correlated materials.
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Efficiency Roll-Off in Organic Light-Emitting Diodes / Effizienz-Roll-Off in Organischen LeuchtdiodenMurawski, Caroline 02 November 2015 (has links) (PDF)
The efficiency of organic light-emitting diodes (OLEDs) typically decreases with increasing current density. This so-called roll-off impedes the market entry of OLEDs in high-brightness applications such as general lighting. One of the most important processes causing roll-off is exciton annihilation, which evolves upon high exciton densities. This mechanism is especially pronounced in phosphorescent molecules due to their long triplet lifetime. In order to reduce the roll-off in phosphorescent OLEDs, this thesis focusses on decreasing the local exciton density by modifying the exciton lifetime, the spatial exciton distribution, and the tendency of emitters to form aggregates. The obtained results lead to a deeper understanding of efficiency roll-off and help sustaining the OLED efficiency at high brightness.
The emitter lifetime can be influenced by the optical environment around the emitting dipoles through the Purcell effect. In order to study this effect, the distance between emitter and metal cathode is varied for two different OLED stacks. A strong influence of emitter position and orientation on roll-off is observed and explained by modelling the data with triplet-triplet annihilation theory. Furthermore, design principles for optimal high-brightness performance are established by simulating the roll-off as a function of emitter-cathode distance, emissive dipole orientation, and radiative efficiency.
Next, a method is developed that allows extracting the spatial exciton distribution. Therefore, a thin sensing layer that locally quenches excitons is introduced into the emission layer at varying positions.
The resulting quenching profile is then fitted using a comprehensive theory based on the diffusion equation, which renders the exciton distribution and diffusion length with nanometer resolution. This method is applied to an emission layer comprising an ambipolar host material. Contrary to expectations which suggest that ambipolar materials exhibit broad exciton formation, a narrow emission zone close to the electron transport layer is found. Additional explorations of structures that might broaden the emission zone point to a narrow emission zone in double emission layers and broader exciton formation in mixed emission layers.
Previous investigations revealed a strong correlation between emitter aggregation and molecular dipole moment of the emitter. Within this thesis, the range of studied emitters is significantly extended. It is shown that homoleptic emitters show a stronger tendency to form aggregates than heteroleptic compounds. This is probably not only related to their higher dipole-dipole potential, but also to the molecular structure. Systematic analysis of the deposition parameters shows that aggregate formation depends on the underlying material and increases with increasing substrate temperature and decreasing evaporation rate.
The two green emitters Ir(ppy)3 and Ir(ppy)2(acac) are additionally studied by means of X-ray diffraction. Both emitters form crystallite grains and exhibit a preferred orientation. Doping the emitters into an amorphous host, both orientation and crystallite formation retain at the investigated doping concentrations above 20 wt%. This result is a first step toward further understanding of the mechanism of transition dipole orientation. / Die Effizienz organischer Leuchtdioden (OLEDs) nimmt üblicherweise mit ansteigender Stromdichte ab. Dieser so genannte Roll-Off erschwert den Markteintritt von OLEDs in Bereichen, die hohe Helligkeiten erfordern, wie beispielsweise in der Beleuchtung. Einer der wichtigsten Prozesse, die zu Roll-Off führen, ist die Annihilation von Exzitonen. Diese nimmt mit steigender Exzitonendichte zu und ist vor allem in phosphoreszenten OLEDs aufgrund der dort vorhandenen langen Triplettlebensdauer ein großer Verlustfaktor. Im Rahmen dieser Dissertation werden Methoden vorgestellt, die mittels Reduzierung der Exzitonendichte den Roll-Off in phosphoreszenten OLEDs verringern können. Dazu gehören die Veränderung der Exzitonenlebensdauer, die Untersuchung der räumlichen Verteilung der Exzitonen und die Erforschung der Bildung von Emitteraggregaten. Die gewonnenen Ergebnisse führen zu einem besseren Verständnis des Effizienz Roll-Offs und helfen, die Effizienz von OLEDs bei hohen Helligkeiten zu verbessern.
Die Emitterlebensdauer kann über den Purcell-Effekt durch Veränderung des die emittierenden Dipole umgebenden elektromagnetischen Felds beeinflusst werden. Dieser Effekt wird genutzt, indem der Abstand zwischen Emitter und Metallelektrode für zwei verschiedene OLED-Aufbauten variiert wird. Der Roll-Off ist stark abhängig von der Position und Orientierung des Emitters und kann durch Modellierung der Daten auf Basis von Triplett-Triplett-Annihilation erklärt werden. Durch Simulation des Roll-Offs in Abhängigkeit des Emitter-Kathode-Abstands, der Orientierung und der strahlenden Effizienz der emittierenden Dipole werden Prinzipien zur optimalen Leistung von OLEDs bei hohen Helligkeiten entwickelt.
Als nächstes wird eine Methode eingeführt mittels derer die räumliche Exzitonenverteilung extrahiert werden kann. Dafür wird eine dünne Sensorschicht in die Emissionsschicht eingebracht, die lokal Exzitonen auslöscht. Unter Variation der Position des Sensors wird ein Profil der Auslöschungsintensität bestimmt. Die gemessene Intensität wird mittels einer umfassenden Theorie auf Grundlage der Diffusionsgleichung angepasst, wodurch sich die räumliche Verteilung der Exzitonen und die Diffusionslänge mit einer Auflösung von 1nm ergibt. Die Methode wird auf eine Emissionsschicht angewandt, die das ambipolare Matrixmaterial CBP enthält. Entgegen der Erwartung, dass die Exzitonenbildung in ambipolaren Materialien weiter ausgedehnt ist, ist die gemessene Emissionszone sehr schmal und befindet sich an der Grenze zur Elektronentransportschicht. Um eine Verbreiterung des Emissionsprofils zu ermöglichen, werden weitere Strukturen untersucht. Dabei wird eine schmale Emissionszone in Doppelemissionsschichten beobachtet, wohingegen gemischte Emissionsschichten zu einer Verbreiterung der Exzitonenbildung führen können.
Vorangegangene Untersuchungen deckten einen Zusammenhang zwischen der Aggregation von Emittermolekülen und dem Dipolmoment des Emitters auf. In dieser Arbeit werden weitere Emittermoleküle untersucht, wobei eine stärkere Aggregation von homoleptischen Emittern im Vergleich zu heteroleptischen festgestellt wird. Dies ist einerseits im höheren Dipol-Dipol-Potential der homoleptischen Verbindungen und andererseits in der Molekülstruktur begründet. Eine systematische Analyse der Herstellungsparameter zeigt, dass die Aggregatbildung von dem darunter liegenden Material abhängt und mit steigender Substrattemperatur und sinkender Verdampfungsrate zunimmt.
Die zwei Grünemitter Ir(ppy)3 und Ir(ppy)2(acac) werden zusätzlich mittels Röntgenspektroskopie untersucht. Beide Emitter bilden kristalline Körner und weisen eine bevorzugte Orientierung auf. Sowohl die Kristallbildung als auch die Orientierung bleiben erhalten, wenn die Emitter mit mehr als 20 Gewichtsprozent in das Matrixmaterial CBP dotiert werden. Dieses Ergebnis ist ein erster Schritt zum besseren Verständnis der in vielen Iridium-Emittern beobachteten Orientierung des Übergangsdipolmoments.
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Οπτικές ιδιότητες κβαντικών τελειών CuInS2 /ZnS με τεχνικές φασματοσκοπίας σταθερής κατάστασης και χρονικής ανάλυσηςΔροσερός, Νικόλαος 07 July 2015 (has links)
Στην παρούσα Ειδική Ερευνητική Εργασία ερευνώνται οι οπτικές ιδιότητες των νανοκρυσταλλικών κβαντικών τελειών CuInS2/ZnS, γνωστές ως CIS/ZnS QDs, τόσο με τη χρήση φασματοσκοπίας σταθερής κατάστασης όσο και με τη χρήση φασματοσκοπίας χρονικής ανάλυσης με την τεχνική Time Correlated Single Photon Counting. Ειδικότερα, διερευνώνται οι μηχανισμοί που εμπλέκονται στη διαδικασία της εκπομπής φωτός, η επίδραση που έχει η πολικότητα του διαλύτη και η συγκέντρωση των κβαντικών τελειών, όταν είναι διαλυμένες εντός διαλύματος, καθώς και η αλληλεπίδραση μεταξύ των κβαντικών τελειών όταν είναι εναποτιθέμενες σε υμένια, είτε με την τεχνική drop-casting είτε με spin-coating.
Τόσο η αύξηση της συγκέντρωσης των κβαντικών τελειών όσο και η αύξηση της πολικότητας του διαλύτη προκάλεσε τη μετατόπιση του εξιτονικού ώμου και του μήκους κύματος μέγιστης εκπομπής προς το ερυθρό, στα φάσματα σταθερής κατάστασης. Επίσης η μετατόπιση της φωτοφωταύγειας των CIS/ZnS QDs προς το ερυθρό ήταν μεγαλύτερη στα υμένια που είχαν παρασκευασθεί με την τεχνική drop-casting από τα υμένια με το ίδιο υπόστρωμα που είχαν παρασκευασθεί με την τεχνική spin-coating.
Με χρήση φασματοσκοπίας χρονικής ανάλυσης, ανιχνεύθηκε η ύπαρξη τριών μηχανισμών στα διαλύματα με χρόνους ζωής 1-3, 20-40 και 200-300 ns, ενώ στα υμένια προστέθηκε ένας επιπλέον μηχανισμός με χρόνο ζωής από μερικές εκατοντάδες ps έως 4 ns. Ο χαρακτήρας της αποδιέγερσης των QDs στα υμένια κυμαίνεται μεταξύ διεκθετικού και τετραεκθετικού ανάλογα με το δείγμα και το μήκος κύματος ανίχνευσης. Το περίεργο χαρακτηριστικό του νέου μηχανισμού που ανιχνεύθηκε στα υμένια είναι ότι γίνεται πιο γρήγορος και πιο αποδοτικός καθώς το μήκος κύματος ανίχνευσης αυξάνει. Ένας παρόμοιος μηχανισμός δεν έχει αναφερθεί σε άλλες εργασίες με CIS/ZnS QDs, ενώ έχει αναφερθεί σε παλιότερες εργασίες με PbS QDs τόσο σε διαλύματα όσο και σε στερεά υμένια. Η μετατόπιση των πυκνών υμενίων προς το ερυθρό σε σχέση με τα αραιά αποτελεί ένδειξη της ύπαρξης μεταφοράς ενέργειας μεταξύ QDs διαφορετικών μεγεθών. / In this Master Thesis, the optical properties of CuInS2/ZnS nanocrystal quantum dots are investigated. For this purpose both steady state and time resolved spectroscopy, specifically the Time Correlated Single Photon Counting technique, were used. The photoluminescence properties of CuInS2/ZnS quantum dots, commonly known as CIS/ZnS QDs, either dissolved in solutions of different concentrations and solvent polarities or deposited on films made by spin-coating or drop-casting are studied.
Either in the absorption and the photoluminescence steady state spectra, a red-shift both in the excitonic transition and the wavelength of the maximum intensity was observed as the concentration of the CIS/ZnS QDs or the polarity of the solvent increased. In films, a red-shifted photoluminescence spectrum is observed for films made by drop-casting compared to those prepared by spin-coating, having the same substrate material.
By using time-resolved photoluminescence spectroscopy a three-exponential decay was observed in solutions, with time constants 1-3, 20-40 and 200-300 ns, while decays in films, apart from the three mechanisms also observed in solutions, also exhibit a fast decay component with a lifetime varying from some hundreds of ps until 4 ns. The attitude of the decay in films varies from two-exponential to four-exponential and it depends on the samples and the detection wavelength. The strange characteristic of the new mechanism which was detected in films is that its lifetime becomes shorter and its pre-exponential factor increases with the detection wavelength. To the best of our knowledge, such a faster decay as the emission wavelength increases has never been reported for CIS/ZnS QDs, but it has been reported for PbS QDs either diluted in solution or deposited in polymeric matrices. The time resolved photoluminescence spectra in the drop-casted films experience a larger transient red-shift than the spin-coated ones, indicative of a possible energy transfer among adjacent QDs with different diameters.
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Ultrafast Raman Loss Spectroscopic Investigations of Excited State Structural Dynamics of Bis(phenylethynyl)benzene and trans-StilbeneMallick, Babita January 2017 (has links) (PDF)
The subject of this thesis is the design and development of a unified set up for femtosecond transient absorption and ultrafast Raman loss spectroscopy and demonstrate its potential in capturing the ultrafast photophysical and photochemical processes with excellent time and frequency resolution. Ultrafast spectroscopy has been serving as a powerful tool for understanding the structural dynamical properties of molecules in the condensed and gas phase. The advent of ultrashort pulses with their high peak power enables the laser spectroscopic community to study molecular reaction dynamics and photophysics that happen at extremely short timescales, ranging from picosecond to femtosecond. These processes can be measured with extremely high time resolution, which helps to resolve the under-lying molecular process. But in order to understand the global mechanism of the underlying molecular processes, we have to resolve the nuclear dynamics with the proper frequency resolution. However, achieving both, time and frequency resolutions simultaneously is not possible according to the Heisenberg uncertainty principle. Later, this limitation was overcome by femtosecond stimulated Raman spectroscopy (FSRS), a third order non-linear Raman spectroscopy. In this thesis we introduced the ultrafast Raman loss spectroscopic (URLS) technique which is analogous to FSRS, offering the modern ultrafast community to resolve molecular processes with better signal-to-noise ratio along with proper time and frequency resolution. We demonstrate the experimental procedure including the single shot detection scheme to measure whitelight background, ground state Ra-man, transient absorption and transient Raman in shot-to-shot detection fashion. URLS has been applied to understand the excited state planarization dynamics of 1,4-bis(phenylethynyl)benzene (BPEB) in different solvents. In addition, excitation wavelength dependent conformational reorganization dynamics of different sub-sets of thermally activated ground state population of BPEB are also discussed. Using the same techniques along with femtosecond transient absorption, we demonstrate the ultrafast vibrational energy transfer and the role of coherent oscillations of low frequency vibrations on the solution phase photo-isomerization of trans-stilbene from an optically excited state. The effects of solvents on the coherent nuclear motion are also discussed in the context of reaction rates.
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Efficiency Roll-Off in Organic Light-Emitting DiodesMurawski, Caroline 28 August 2015 (has links)
The efficiency of organic light-emitting diodes (OLEDs) typically decreases with increasing current density. This so-called roll-off impedes the market entry of OLEDs in high-brightness applications such as general lighting. One of the most important processes causing roll-off is exciton annihilation, which evolves upon high exciton densities. This mechanism is especially pronounced in phosphorescent molecules due to their long triplet lifetime. In order to reduce the roll-off in phosphorescent OLEDs, this thesis focusses on decreasing the local exciton density by modifying the exciton lifetime, the spatial exciton distribution, and the tendency of emitters to form aggregates. The obtained results lead to a deeper understanding of efficiency roll-off and help sustaining the OLED efficiency at high brightness.
The emitter lifetime can be influenced by the optical environment around the emitting dipoles through the Purcell effect. In order to study this effect, the distance between emitter and metal cathode is varied for two different OLED stacks. A strong influence of emitter position and orientation on roll-off is observed and explained by modelling the data with triplet-triplet annihilation theory. Furthermore, design principles for optimal high-brightness performance are established by simulating the roll-off as a function of emitter-cathode distance, emissive dipole orientation, and radiative efficiency.
Next, a method is developed that allows extracting the spatial exciton distribution. Therefore, a thin sensing layer that locally quenches excitons is introduced into the emission layer at varying positions.
The resulting quenching profile is then fitted using a comprehensive theory based on the diffusion equation, which renders the exciton distribution and diffusion length with nanometer resolution. This method is applied to an emission layer comprising an ambipolar host material. Contrary to expectations which suggest that ambipolar materials exhibit broad exciton formation, a narrow emission zone close to the electron transport layer is found. Additional explorations of structures that might broaden the emission zone point to a narrow emission zone in double emission layers and broader exciton formation in mixed emission layers.
Previous investigations revealed a strong correlation between emitter aggregation and molecular dipole moment of the emitter. Within this thesis, the range of studied emitters is significantly extended. It is shown that homoleptic emitters show a stronger tendency to form aggregates than heteroleptic compounds. This is probably not only related to their higher dipole-dipole potential, but also to the molecular structure. Systematic analysis of the deposition parameters shows that aggregate formation depends on the underlying material and increases with increasing substrate temperature and decreasing evaporation rate.
The two green emitters Ir(ppy)3 and Ir(ppy)2(acac) are additionally studied by means of X-ray diffraction. Both emitters form crystallite grains and exhibit a preferred orientation. Doping the emitters into an amorphous host, both orientation and crystallite formation retain at the investigated doping concentrations above 20 wt%. This result is a first step toward further understanding of the mechanism of transition dipole orientation.:List of Publications
1 Introduction
2 Principles of Organic Semiconductors
2.1 Molecular Orbitals
2.2 Optical Properties
2.3 Intermolecular Energy Transfer
2.4 Charge Transport
2.5 Organic Light-Emitting Diodes
2.5.1 Structure and Working Principle
2.5.2 Characterization
3 Theory of Efficiency Roll-Off
3.1 Current Status
3.2 Processes Leading to Roll-Off
3.2.1 Triplet-Triplet Annihilation
3.2.2 Triplet-Polaron Interaction
3.2.3 Further Processes Influencing Roll-Off
3.3 Interplay of the Various Processes
3.4 Scope of this Work
4 Experimental Methods
4.1 Sample Preparation
4.2 Measurement
4.2.1 Thin-Film Characterization
4.2.2 OLED Characterization
4.3 Materials
4.3.1 Electrodes, Transport Materials, and Blockers
4.3.2 Materials of the Emission Layer
5 Influence of the Optical Environment
5.1 Introduction
5.2 Influence of Emitter-Cathode Distance
5.3 Emitter Lifetime and Orientation
5.4 Correlation of Roll-Off and Orientation
5.5 Simulation of Roll-Off
5.5.1 Influence of the Electroluminescence Spectrum
5.5.2 Influence of Orientation and Radiative Efficiency
5.6 Conclusion
6 Influence of the Emission Profile
6.1 Preliminary Considerations
6.1.1 Exciton Generation and Diffusion
6.1.2 Width of the Emission Zone
6.1.3 Dependence on the Structure of the Emission Layer
6.2 Measurement of the Emission Profile
6.2.1 Method
6.2.2 Mathematical Description
6.2.3 Experimental Realization and Evaluation
6.3 Ambipolar Matrix Materials
6.3.1 Device Performance
6.3.2 Influence of the Sensing Layer
6.3.3 Emission Profile
6.4 Double- and Mixed Emission Layers
6.4.1 Emission Profile
6.4.2 Influence of the Matrix Ratio
6.5 Summary and Outlook
7 Influence of Molecular Aggregation
7.1 Introduction
7.2 Aggregation of Homoleptic and Heteroleptic Emitters
7.2.1 Photoluminescence Measurements
7.2.2 Time-Resolved Spectroscopy
7.2.3 X-Ray Diffraction
7.2.4 Conclusions on Emitter Orientation
7.2.5 Comparison of the Different Methods—Emitter Aggregation
7.3 Influence of the Matrix Material
7.3.1 Photoluminescence Measurements
7.3.2 Time-Resolved Spectroscopy
7.4 Influence of Processing Parameters
7.4.1 Substrate Heating
7.4.2 Underlying Layer
7.4.3 Evaporation Rate
7.5 Summary and Implications of Aggregation on Efficiency Roll-Off
8 Summary and Outlook
8.1 Summary of Roll-Off Investigations
8.2 Improving the High-Brightness Performance Further
8.3 Concluding Words on Emitter Orientation
A Appendix to Theory of Efficiency Roll-Off
B Appendix to Emission and Sensing Profiles
B.1 Emission Profiles
B.2 Emission Profiles Including a Sensing Layer
B.3 Sensing Profiles
C Appendix to Double- and Mixed Emission Layers
C.1 Sample Uniformity
C.2 Influence of the Sensor on Current Density
C.3 Further D-EML and M-EML structures
D Appendix to Molecular Aggregation
List of Chemical Compounds
List of Abbreviations
List of Important Symbols
Bibliography
Acknowledgement / Die Effizienz organischer Leuchtdioden (OLEDs) nimmt üblicherweise mit ansteigender Stromdichte ab. Dieser so genannte Roll-Off erschwert den Markteintritt von OLEDs in Bereichen, die hohe Helligkeiten erfordern, wie beispielsweise in der Beleuchtung. Einer der wichtigsten Prozesse, die zu Roll-Off führen, ist die Annihilation von Exzitonen. Diese nimmt mit steigender Exzitonendichte zu und ist vor allem in phosphoreszenten OLEDs aufgrund der dort vorhandenen langen Triplettlebensdauer ein großer Verlustfaktor. Im Rahmen dieser Dissertation werden Methoden vorgestellt, die mittels Reduzierung der Exzitonendichte den Roll-Off in phosphoreszenten OLEDs verringern können. Dazu gehören die Veränderung der Exzitonenlebensdauer, die Untersuchung der räumlichen Verteilung der Exzitonen und die Erforschung der Bildung von Emitteraggregaten. Die gewonnenen Ergebnisse führen zu einem besseren Verständnis des Effizienz Roll-Offs und helfen, die Effizienz von OLEDs bei hohen Helligkeiten zu verbessern.
Die Emitterlebensdauer kann über den Purcell-Effekt durch Veränderung des die emittierenden Dipole umgebenden elektromagnetischen Felds beeinflusst werden. Dieser Effekt wird genutzt, indem der Abstand zwischen Emitter und Metallelektrode für zwei verschiedene OLED-Aufbauten variiert wird. Der Roll-Off ist stark abhängig von der Position und Orientierung des Emitters und kann durch Modellierung der Daten auf Basis von Triplett-Triplett-Annihilation erklärt werden. Durch Simulation des Roll-Offs in Abhängigkeit des Emitter-Kathode-Abstands, der Orientierung und der strahlenden Effizienz der emittierenden Dipole werden Prinzipien zur optimalen Leistung von OLEDs bei hohen Helligkeiten entwickelt.
Als nächstes wird eine Methode eingeführt mittels derer die räumliche Exzitonenverteilung extrahiert werden kann. Dafür wird eine dünne Sensorschicht in die Emissionsschicht eingebracht, die lokal Exzitonen auslöscht. Unter Variation der Position des Sensors wird ein Profil der Auslöschungsintensität bestimmt. Die gemessene Intensität wird mittels einer umfassenden Theorie auf Grundlage der Diffusionsgleichung angepasst, wodurch sich die räumliche Verteilung der Exzitonen und die Diffusionslänge mit einer Auflösung von 1nm ergibt. Die Methode wird auf eine Emissionsschicht angewandt, die das ambipolare Matrixmaterial CBP enthält. Entgegen der Erwartung, dass die Exzitonenbildung in ambipolaren Materialien weiter ausgedehnt ist, ist die gemessene Emissionszone sehr schmal und befindet sich an der Grenze zur Elektronentransportschicht. Um eine Verbreiterung des Emissionsprofils zu ermöglichen, werden weitere Strukturen untersucht. Dabei wird eine schmale Emissionszone in Doppelemissionsschichten beobachtet, wohingegen gemischte Emissionsschichten zu einer Verbreiterung der Exzitonenbildung führen können.
Vorangegangene Untersuchungen deckten einen Zusammenhang zwischen der Aggregation von Emittermolekülen und dem Dipolmoment des Emitters auf. In dieser Arbeit werden weitere Emittermoleküle untersucht, wobei eine stärkere Aggregation von homoleptischen Emittern im Vergleich zu heteroleptischen festgestellt wird. Dies ist einerseits im höheren Dipol-Dipol-Potential der homoleptischen Verbindungen und andererseits in der Molekülstruktur begründet. Eine systematische Analyse der Herstellungsparameter zeigt, dass die Aggregatbildung von dem darunter liegenden Material abhängt und mit steigender Substrattemperatur und sinkender Verdampfungsrate zunimmt.
Die zwei Grünemitter Ir(ppy)3 und Ir(ppy)2(acac) werden zusätzlich mittels Röntgenspektroskopie untersucht. Beide Emitter bilden kristalline Körner und weisen eine bevorzugte Orientierung auf. Sowohl die Kristallbildung als auch die Orientierung bleiben erhalten, wenn die Emitter mit mehr als 20 Gewichtsprozent in das Matrixmaterial CBP dotiert werden. Dieses Ergebnis ist ein erster Schritt zum besseren Verständnis der in vielen Iridium-Emittern beobachteten Orientierung des Übergangsdipolmoments.:List of Publications
1 Introduction
2 Principles of Organic Semiconductors
2.1 Molecular Orbitals
2.2 Optical Properties
2.3 Intermolecular Energy Transfer
2.4 Charge Transport
2.5 Organic Light-Emitting Diodes
2.5.1 Structure and Working Principle
2.5.2 Characterization
3 Theory of Efficiency Roll-Off
3.1 Current Status
3.2 Processes Leading to Roll-Off
3.2.1 Triplet-Triplet Annihilation
3.2.2 Triplet-Polaron Interaction
3.2.3 Further Processes Influencing Roll-Off
3.3 Interplay of the Various Processes
3.4 Scope of this Work
4 Experimental Methods
4.1 Sample Preparation
4.2 Measurement
4.2.1 Thin-Film Characterization
4.2.2 OLED Characterization
4.3 Materials
4.3.1 Electrodes, Transport Materials, and Blockers
4.3.2 Materials of the Emission Layer
5 Influence of the Optical Environment
5.1 Introduction
5.2 Influence of Emitter-Cathode Distance
5.3 Emitter Lifetime and Orientation
5.4 Correlation of Roll-Off and Orientation
5.5 Simulation of Roll-Off
5.5.1 Influence of the Electroluminescence Spectrum
5.5.2 Influence of Orientation and Radiative Efficiency
5.6 Conclusion
6 Influence of the Emission Profile
6.1 Preliminary Considerations
6.1.1 Exciton Generation and Diffusion
6.1.2 Width of the Emission Zone
6.1.3 Dependence on the Structure of the Emission Layer
6.2 Measurement of the Emission Profile
6.2.1 Method
6.2.2 Mathematical Description
6.2.3 Experimental Realization and Evaluation
6.3 Ambipolar Matrix Materials
6.3.1 Device Performance
6.3.2 Influence of the Sensing Layer
6.3.3 Emission Profile
6.4 Double- and Mixed Emission Layers
6.4.1 Emission Profile
6.4.2 Influence of the Matrix Ratio
6.5 Summary and Outlook
7 Influence of Molecular Aggregation
7.1 Introduction
7.2 Aggregation of Homoleptic and Heteroleptic Emitters
7.2.1 Photoluminescence Measurements
7.2.2 Time-Resolved Spectroscopy
7.2.3 X-Ray Diffraction
7.2.4 Conclusions on Emitter Orientation
7.2.5 Comparison of the Different Methods—Emitter Aggregation
7.3 Influence of the Matrix Material
7.3.1 Photoluminescence Measurements
7.3.2 Time-Resolved Spectroscopy
7.4 Influence of Processing Parameters
7.4.1 Substrate Heating
7.4.2 Underlying Layer
7.4.3 Evaporation Rate
7.5 Summary and Implications of Aggregation on Efficiency Roll-Off
8 Summary and Outlook
8.1 Summary of Roll-Off Investigations
8.2 Improving the High-Brightness Performance Further
8.3 Concluding Words on Emitter Orientation
A Appendix to Theory of Efficiency Roll-Off
B Appendix to Emission and Sensing Profiles
B.1 Emission Profiles
B.2 Emission Profiles Including a Sensing Layer
B.3 Sensing Profiles
C Appendix to Double- and Mixed Emission Layers
C.1 Sample Uniformity
C.2 Influence of the Sensor on Current Density
C.3 Further D-EML and M-EML structures
D Appendix to Molecular Aggregation
List of Chemical Compounds
List of Abbreviations
List of Important Symbols
Bibliography
Acknowledgement
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Constructing and Commissioning HELIOS – A High Harmonic Generation Source for Pump-Probe Measurements with sub 50 fs Temporal Resolution : The Development of Experimental Equipment for Extreme Ultraviolet SpectroscopyTerschlüsen, Joachim A. January 2016 (has links)
This thesis presents HELIOS, an in-house laboratory for time-resolved pump-probe spectroscopy with extreme-ultraviolet (XUV) probe radiation. A wide span of pump wavelengths can be generated using commercial laser equipment while XUV probe radiation is generated via a high harmonic generation process in a noble gas delivering probe photons with energies between 20 eV and 72 eV. The XUV beam path features a time-preserving monochromator and was constructed and built in-house. HELIOS features an overall time resolution of about 50 fs when using 800 nm pump and 41 eV probe photons. An energy resolution of 110 meV at 41 eV photon energy can be achieved. HELIOS features two beamlines. One µ-focus beamline with an XUV focal size of about 20 µm can be used with experiments that require such a small XUV focal size as well as with different end stations. The other beamline features a semi-permanently mounted end station for angle-resolved photoelectron spectroscopy under ultra-high vacuum conditions. Experiments demonstrating the usability of HELIOS and the two beamlines are presented. A pump-probe measurement on graphene demonstrates the capability of determining a large part of the k-space in only one measurement due to the use of an ARTOF angle-resolved time-of-flight electron spectrometer. A non-angle-resolved pump-probe measurement on the conducting polymer PCPDTBT demonstrates the high signal-to-noise ratio achievable at this beamline in non-angle-resolved photoelectron-spectroscopy pump-probe measurements. The usability of the µ-focus beamline is demonstrated with time-resolved measurements on magnetic samples employing an in-house-designed spectrometer. These experiments allow the retrieval of element-specific information on the magnetization within a sample employing the transversal magneto-optical Kerr effect (T-MOKE). Additionally, a Fourier transform spectrometer for the XUV is presented, the concept was tested at a synchrotron and it was used to determine the longitudinal coherence of the XUV radiation at HELIOS.
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