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Als Wärmedämmstoffe werden üblicherweise makroporöse Stoffsysteme wie Schäume, Pul-verschüttungen, Faservliese und – wolle eingesetzt. Zusätzlich finden mikro- und mesoporöse Dämmstoffe wie Aerogele Anwendung. Um effiziente Wärmedämmstoffe entwickeln zu können, muss der Gesamtwärmetransport in porösen Materialien verstanden werden. Die ein-zelnen Wärmetransport-Mechanismen Festkörperwärmeleitung, Gaswärmeleitung und Wärme-strahlung können zuverlässig analytisch beschrieben werden. Bei manchen porösen Materialien liefert jedoch auch eine Wechselwirkung zwischen den verschiedenen Wärmetransport-Mechanismen, d.h. die Kopplung von Festkörper- und Gaswärmeleitung, einen hohen Beitrag zur Gesamtwärmeleitfähigkeit. Wie hoch dieser Kopplungseffekt bei einer bestimmten Probe ausfällt, kann bisher schwer abgeschätzt werden. Um den Kopplungseffekt von Festkörper- und Gaswärmeleitung besser zu verstehen, sind sowohl experimentelle als auch theoretische Untersuchungen an verschiedenen porösen Stoffsystemen erforderlich. Zusätzlich kann ein zuverlässiges theoretisches Modell dazu beitragen, die mittlere Porengröße von porösen Mate-rialien zerstörungsfrei anhand von gasdruckabhängigen Wärmeleitfähigkeitsmessungen zu bestimmen.
Als Modellsystem für die experimentellen Untersuchungen wurde der hochporöse Feststoff Aerogel verwendet, da seine strukturellen Eigenschaften wie Porengröße und Dichte während der Synthese gut eingestellt werden können. Es wurden Resorcin-Formaldehyd-Aerogele mit mittleren Porengrößen von etwa 600 nm, 1 µm und 8 µm sowie daraus mittels Pyrolyse abge-leitete Kohlenstoff-Aerogele synthetisiert und jeweils hinsichtlich ihrer Struktur und Wärme-leitfähigkeiten experimentell charakterisiert. Die Gesamtwärmeleitfähigkeiten dieser Aerogele wurden für verschiedene Gasatmosphären (Kohlenstoffdioxid, Argon, Stickstoff und Helium) in Abhängigkeit vom Gasdruck durch das Hitzdraht-Verfahren bestimmt. Hierfür wurde der Messbereich der Hitzdraht-Apparatur des ZAE Bayern mittels einer Druckzelle auf 10 MPa erweitert. Die Messergebnisse zeigen, dass bei allen Aerogel-Proben Festkörper- und Gaswär-meleitung einen deutlichen Kopplungsbeitrag liefern: Die gemessenen gasdruckabhängigen Wärmeleitfähigkeiten sind um Faktor 1,3 bis 3,3 höher als die entsprechenden reinen Gas-wärmeleitfähigkeiten. Die jeweilige Höhe hängt sowohl vom verwendeten Gas (Gaswärmeleitfähigkeit) als auch vom Aerogeltyp (Festkörperwärmeleitfähigkeit und Festkörperstruktur) ab. Ein stark vernetzter Festkörper verursacht beispielsweise einen niedrigeren Kopplungsbei-trag als ein weniger stark vernetzter Festkörper.
Andererseits wurde die gasdruckabhängige Wärmeleitfähigkeit von Melaminharzschaum – einem flexiblen, offenporigen und hochporösen Material – in einer evakuierbaren Zwei-Plattenapparatur unter Stickstoff-Atmosphäre bestimmt. Das Material zeichnet sich dadurch aus, dass die Addition der Einzelwärmeleitfähigkeiten gut erfüllt ist, d.h. kein Kopplungsef-fekt auftritt. Allerdings konnte gezeigt werden, dass die gestauchte und damit unregelmäßige Struktur von Melaminharzschaum die Kopplung von Festkörper- und Gaswärmeleitung deut-lich begünstigt. Je stärker die Melaminharzschaumprobe komprimiert wird, umso stärker fällt der Kopplungseffekt aus. Bei einer Kompression um 84 % ist beispielsweise die gemessene gasdruckabhängige Wärmeleitfähigkeit bei 0,1 MPa um ca. 17 % gegenüber der effektiven Wärmeleitfähigkeit von freiem Stickstoff erhöht.
Die experimentellen Untersuchungen wurden durch theoretische Betrachtungen ergänzt. Zum einen wurde die Kopplung von Festkörper- und Gaswärmeleitung anhand einer Serienschal-tung der thermischen Widerstände von Festkörper- und Gasphase dargestellt, um die Abhän-gigkeit von verschiedenen Parametern zu untersuchen. Dadurch konnte gezeigt werden, dass der Kopplungsterm stets von den Verhältnissen aus Festkörper- und Gaswärmeleitfähigkeit sowie aus den geometrischen Parametern beider Phasen abhängt. Des Weiteren wurden mit dem Computerprogramm HEAT2 Finite-Differenzen-Simulationen an Modellstrukturen durchgeführt, die für poröse Stoffsysteme, insbesondere Aerogel, charakteristisch sind (Stege, Hälse, Windungen und tote Enden). Die simulierten gasdruckabhängigen Wärmeleitfähigkeiten zeigen deutlich, dass die Festkörperstruktur mit der geringsten Vernetzung, d.h. das tote Ende, am meisten zur Kopplung von Festkörper- und Gaswärmeleitung beiträgt. Dies korre-liert mit den experimentellen Ergebnissen. Darüber hinaus kann man erkennen, dass die Ge-samtwärmeleitfähigkeit eines schlecht vernetzten porösen Systems, wo also ein hoher Kopp-lungseffekt (Serienschaltung) auftritt, niemals größer wird als die eines gut vernetzten Sys-tems mit gleicher Porosität, wo hauptsächlich paralleler Wärmetransport durch beide Phasen stattfindet.
Schließlich wurden drei Modelle entwickelt bzw. modifiziert, um die gasdruckabhängige Wärmeleitfähigkeit von porösen Stoffsystemen theoretisch beschreiben zu können. Zunächst wurde ein für Kugelschüttungen entwickeltes Modell für Aerogel angepasst, d.h. Kopplung von Festkörper- und Gaswärmeleitung wurde nur in den Lücken zwischen zwei benachbarten Partikeln berücksichtigt. Ein Vergleich mit den Messkurven zeigt, dass der ermittelte Kopplungsterm zu gering ausfällt. Daher wurde ein bereits existierendes Aerogelmodell mit kubischer Einheitszelle, welches zusätzlich Kopplung zwischen den einzelnen Partikelsträngen beinhaltet, verbessert. Auch dieses Modell liefert keine zufriedenstellende Übereinstimmung mit den Messwerten, denn der Kopplungsbeitrag wird immer noch unterschätzt. Das liegt daran, dass die gewählte regelmäßige kubische Struktur für Aerogel zu ungenau ist. So geht bei der Berechnung des Kopplungsterms der bereits erwähnte hohe Beitrag durch tote Enden (und auch Windungen) verloren. Erfahrungsgemäß können jedoch alle für Aerogel erhaltenen gasdruckabhängigen Messkurven mit dem sogenannten Skalierungsmodell relativ gut beschrieben werden. Das entspricht dem Knudsen-Modell für reine Gaswärmeleitung, welches mit einem konstanten Faktor skaliert wird. Die Anwendung dieses einfachen Modells auf die Messdaten hat gezeigt, dass die Akkommodationskoeffizienten von Helium in Aerogel deut-lich höher sind als die Literaturwerte (ca. 0,3 auf Metalloberflächen): In den vermessenen RF- und Kohlenstoff-Aerogelen lassen sich Akkommodationskoeffizienten nahe 1 für Helium ab-leiten. Darüber hinaus ist das Skalierungsmodell gut geeignet, die mittleren Porengrößen poröser Materialien zuverlässig aus gasdruckabhängig gemessenen Wärmeleitfähigkeitskurven zu bestimmen. Dies stellt somit eine unkomplizierte und zerstörungsfreie Charakterisierungsmethode dar.
In order to shrink the size of semiconductor devices and improve their
efficiency at the same time, silicon-based semiconductor devices have
been engineered, until the material almost reaches its performance
limits. As the candidate to be used next in semiconducting devices,
single-wall carbon nanotubes show a great potential due to their
promise of increased device efficiency and their high charge carrier
mobilities in the nanometer size active areas. However, there are
material based problems to overcome in order to imply SWNTs in the
semiconductor devices. SWNTs tend to aggregate in bundles and it is
not trivial to obtain an electronically or chirally homogeneous SWNT
dispersion and when it is done, a homogeneous thin film needs to be
produced with a technique that is practical, easy and scalable. This
work was aimed to solve both of these problems.
In the first part of this study, six different polymers, containing
fluorene or carbazole as the rigid part and bipyridine, bithiophene or
biphenyl as the accompanying copolymer unit, were used to selectively
disperse semiconducting SWNTs. With the data obtained from
absorption and photoluminescence spectroscopy of the corresponding
dispersions, it was found out that the rigid part of the copolymer plays a
primary role in determining its dispersion efficiency and electronic
sorting ability. Within the two tested units, carbazole has a higher π
electron density. Due to increased π−π interactions, carbazole
containing copolymers have higher dispersion efficiency. However, the
electronic sorting ability of fluorene containing polymers is superior.
Chiral selection of the polymers in the dispersion is not directly
foreseeable from the selection of backbone units. At the end, obtaining a monochiral dispersion is found to be highly dependent on the used raw
material in combination to the preferred polymer.
Next, one of the best performing polymers due to high chirality
enrichment and electronic sorting ability was chosen in order to
disperse SWNTs. Thin films of varying thickness between 18 ± 5 to
755o±o5 nm were prepared using vacuum filtration wet transfer method
in order to analyze them optically and electronically.
The scalability and efficiency of the integrated thin film production
method were shown using optical, topographical and electronic
measurements. The relative photoluminescence quantum yield of the
radiative decay from the SWNT thin films was found to be constant for
the thickness scale. Constant roughness on the film surface and linearly
increasing concentration of SWNTs were also supporting the scalability
of this thin film production method. Electronic measurements on bottom
gate top contact transistors have shown an increasing charge carrier
mobility for linear and saturation regimes. This was caused by the
missing normalization of the mobility for the thickness of the active
layer. This emphasizes the importance of considering this dimension for
comparison of different field effect transistor mobilities.
In the field of organic photovoltaics, one of the most intensely researched topics to date is the charge carrier photogeneration in organic bulk heterojunction solar cells whose thorough understanding is crucial for achieving higher power conversion efficiencies. In particular, the mechanism of singlet exciton dissociation at the polymer–fullerene interface is still controversially debated.
This work addresses the dissociation pathway via relaxed charge transfer states (CTS) by investigating its field dependence for reference material systems consisting of MDMO-PPV and one of the fullerene derivatives PC61BM, bisPCBM and PC71BM. Field dependent photoluminescence (PL(F)) and transient absorption (TA(F)) measurements give insight into the recombination of charge transfer excitons (CTE) and the generation of polarons, respectively. Optically detected magnetic resonance and atomic force microscopy are used to characterize the morphology of the samples.
The comparison of the experimental field dependent exciton recombination recorded by PL(F) and the theoretical exciton dissociation probability given by the Onsager–Braun model yields the exciton binding energy as one of the key parameters determining the dissociation efficiency. The binding energies of both the singlet exciton in neat MDMO-PPV and the CTE in MDMO-PPV:PC61BM 1:1 are extracted, the latter turning out to be significantly reduced with respect to the one of the singlet exciton.
Based on these results, the field dependence of CTE dissociation is evaluated for MDMO-PPV:PC61BM blends with varying fullerene loads by PL(F) and TA(F). For higher PC61BM contents, the CTE binding energies decrease notably. This behavior is ascribed to a larger effective dielectric constant for well-intermixed blends and to an interplay between dielectric constant and CTE delocalization length for phase separated morphologies, emphasizing the importance of high dielectric constants for the charge carrier photogeneration process.
Finally, the CTE binding energies are determined for MDMO-PPV blends with different fullerene derivatives, focusing on the influence of the acceptor LUMO energy. Here, the experimental results suggest the latter having no or at least no significant impact on the binding energy of the CTE. Variations of this binding energy are rather related to different trap levels in the acceptors which seem to be involved in CTS formation.
The presented thesis deals with the investigation of the characteristic physical properties of lead-free double perovskites. For this purpose lead-free double perovskite single crystals were grown from solution. In order to assess the influence of growth temperature on tail states in the material, the crystals were studied using Photoluminescence Excitation (PLE) and Transmission measurements. Additionally, lead-free double perovskite solar cells and thin films were investigated to address the correlation of precursor stoichiometry and solar cell efficiency. In a last step a new earth abundant lead-free double perovskite was introduced and its physical properties were studied by photoluminescene and absorptance. Like this it was possible to assess the suitability of this material for solar cell applications in the future.
Overview of the Organolead Trihalide Perovskite Crystal Area
Studies of perovskite single crystals with high crystallographic quality is an important technological area of the perovskite research, which enables to estimate their full optoelectronic potential, and thus to boost their future applications [26]. It was therefore essential to grow high-quality single crystals with lowest structural as well as chemical defect densities and with a stoichiometry relevant for their thin-film counterparts [26]. Optoelectronic devices, e.g. solar cells, are highly complex systems in which the properties of the active layer (absorber) are strongly influenced by the adjacent layers, so it is not always easy to define the targeted properties and elaborate the design rules for the active layer. Currently, organolead trihalide perovskite (OLTP) single crystals with the structure ABX3 are one of the most studied crystalline systems. These hybrid crystals are solids composed of an organic cation such as methylammonium (A = MA+) or formamidinium (A = FA+) to form a three-dimensional periodic lattice together with the lead cation (B = Pb2+) and a halogen anion such as chloride, bromide or iodide (X = Cl-, Br- or I-) [23]. Among them are methylammonium lead tribromide (MAPbBr3), methylammonium lead triiodide (MAPbI3), as well as methylammonium lead trichloride (MAPbCl3) [62, 63]. Important representatives with the larger cation FA+ are formamidinium lead tribromide (FAPbBr3) and formamidinium lead triiodide (FAPbI3) [23, 64]. Besides the exchange of cations as well as anions, it was possible to grow crystals containing two halogens to obtain mixed crystals with different proportions of chlorine to bromine and bromine to iodine, as it is shown in Figure 70. By varying the mixing ratio of the halogens, it was therefore possible to vary the colour and thus the absorption properties of the crystals [85], as it can be done with thin polycrystalline perovskite films. In addition, since a few years it is also doable to grow complex crystals that contain several cations as well as anions [26, 80, 81]. These include the perovskites double cation – double halide formamidinium lead triiodide – methylammonium lead tribromide (FAPbI3)0.9(MAPbBr3)0.1 (FAMA) [26, 80] and formamidinium lead triiodide – methylammonium lead tribromide – caesium lead tribromide (FAPbI3)0.9(MAPbBr3)0.05(CsPbBr3)0.05 (CsFAMA) [81], which have made a significant contribution to increase the power conversion efficiency (PCE) in thin-film photovoltaics [47, 79, 182]. The growth of crystals to this day is performed exclusively from solution [23, 26, 56, 62]. Important preparation methods are the cooling acid-based precursor solution crystallisation [22], the inverse temperature crystallisation (ITC) [62], and the antisolvent vapour-assistant crystallisation (AVC) [137]. In the cooling crystallisation, the precursor salts AX and PbX2 are dissolved in an aqueous halogen-containing acid at high temperatures [56]. Controlled and slow cooling finally results in a supersaturated precursor solution, which leads to spontaneous nucleation of crystal nuclei, followed by subsequent crystal growth. The ITC method is based on the inverse or retrograde solubility of a dissociated perovskite in an organic solvent [23, 64]. With increasing temperature, the solubility of the perovskite decreases and mm-sized crystals can be grown within a few hours [23]. In the AVC method, the precursors are also dissolved in an organic solvent as well [137]. By slow evaporation of a so-called antisolvent [137], the solubility of the perovskite in the now present solvent mixture decreases and it finally precipitates. In addition, there are many other methods with the goal of growing high quality and large crystals in a short period of
time [60, 61, 233, 310].
The focus of this work is studying recombination mechanisms occurring in organic solar cells, as well as their impact on one of their most important parameters — the open circuit voltage Voc.
Firstly, the relationship between Voc and the respective charge carrier density n in the active layer under open circuit conditions is analyzed. Therefor, a model after Shockley for the open circuit voltage is used, whose validity is proven with the aid of fits to the measured data. Thereby, it is emphasized that the equation is only valid under special conditions. In the used reference system P3HT:PC61BM the fits are in agreement with the measurement data only in the range of high temperatures (150 - 300 K), where Voc increases linearly with decreasing temperature. At lower temperatures (50 – 150 K), the experiment shows a saturation of Voc. This saturation cannot be explained with the model by the measured falling charge carrier density with decreasing temperatures. In this temperature range Voc is not directly related to the intrinsic properties of the active layer. Voc saturation is due to injection energy barriers at the contacts, which is ascertained by macroscopic simulations. Furthermore, it is observed that Voc in the case of saturation is equivalent to the so-called built-in potential. The difference between the built-in potential and the energy gap corresponds thereby to the sum of the energy barriers at both contacts.
With the knowledge of the Voc(n) dependency for not contact limited solar cells, it is possible to investigate the recombination mechanisms of charge carriers in the active layer. For Langevin recombination the recombination rate is Rn2 (recombination order RO = 2), for Shockley-Read-Hall (SRH) Rn1 (RO=1); in various publications RO higher than two is reported with two main explanations.
1: Trap states for charge carriers exist in the respective separated phases, i.e. electrons in the acceptor phase and holes in the donor phase, which leads to a delayed recombination of the charge carriers at the interface of both phases and finally to an apparent recombination order higher than 2.
2: The enhanced R(n) dependency is attributed to the so called recombination prefactor, which again is dependent from n dependent mobility µ.
It is shown that for the system P3HT:PC61BM at room temperature the µ(n) dependency does nearly completely explain the higher RO but not at lower temperatures which in this case supports the first explanation. In the material system PTB7:PC71BM the increased RO cannot be explained by the µ(n) dependency even at room temperature.
To support the importance of trap states in combination with a phase separation for the explanation of the enhanced RO, additional trap states were incorporated in the solar cells to investigate their influence on the recombination mechanisms. To achieve this, P3HT:PC61BM solar cells were exposed to synthetic air (in the dark and under illumination) or TCNQ was added in small concentrations to the active layer which act as electron traps. For the oxygen degraded solar cell the recombination order is determined by a combination of open Voc-transients and Voc(n) measurements. Thereby, a continuous increase of the recombination order from 2.4 to more than 5 is observed with higher degradation times. By the evaluation of the ideality factor it can be shown that the impact of SRH recombination is increasing with higher trap concentration in relation to Langevin recombination. A similar picture is revealed for solar cells with TCNQ as extrinsic trap states.
Finally, a phenomenon called s-shaped IV-curves is investigated, which can sometimes occur for solar cells under illumination. As course of this a reduced surface recombination velocity can be found. Experimentally, the solar cells were fabricated using a special plasma treatment of the ITO contact. The measured IV-curves of such solar cells are reproduced by macroscopic simulations, where the surface recombination velocity is reduced. Hereby, it has to be distinguished between the surface recombination of majority and minority charge carriers at the respective contacts. The theory can be experimentally confirmed by illumination level dependent IV-curves as well as short circuit current density and open circuit voltage transients.
In dieser Arbeit werden Quantenpunkt-Speichertransistoren basierend auf modulationsdotierten GaAs/AlGaAs Heterostrukturen mit vorpositionierten InAs Quantenpunkten vorgestellt, welche in Abhängigkeit der Ladung auf den Quantenpunkten unterschiedliche Widerstände und Kapazitäten aufweisen. Diese Ladungsabhängigkeiten führen beim Anlegen von periodischen Spannungen zu charakteristischen, durch den Ursprung gehenden Hysteresen in der Strom-Spannungs- und der Ladungs-Spannungs-Kennlinie. Die ladungsabhängigen Widerstände und Kapazitäten ermöglichen die Realisierung von neuromorphen Operationen durch Nachahmung von synaptischen Funktionalitäten und arithmetischen Operationen durch Integration von Spannungs- und Lichtpulsen.
Continuously increasing energy prices have considerably influenced the cost of living over the last decades. At the same time increasingly extreme weather conditions, drought-filled summers as well as autumns and winters with heavier rainfall and worsening storms have been reported. These are possibly the harbingers of the expected approaching global climate change. Considering the depletability of fossil energy sources and a rising distrust in nuclear power, investigations into new and innovative renewable energy sources are necessary to prepare for the coming future.
In addition to wind, hydro and biomass technologies, electricity generated by the direct conversion of incident sunlight is one of the most promising approaches. Since the syntheses and detailed studies of organic semiconducting polymers and fullerenes were intensified, a new kind of solar cell fabrication became conceivable. In addition to classical vacuum deposition techniques, organic cells were now also able to be processed from a solution, even on flexible substrates like plastic, fabric or paper.
An organic solar cell represents a complex electrical device influenced for instance by light interference for charge carrier generation. Also charge carrier recombination and transport mechanisms are important to its performance. In accordance to Coulomb interaction, this results in a specific distribution of the charge carriers and the electric field, which finally yield the measured current-voltage characteristics. Changes of certain parameters result in a complex response in the investigated device due to interactions between the physical processes. Consequently, it is necessary to find a way to generally predict the response of such a device to temperature changes for example.
In this work, a numerical, one-dimensional simulation has been developed based on the drift-diffusion equations for electrons, holes and excitons. The generation and recombination rates of the single species are defined according to a detailed balance approach. The Coulomb interaction between the single charge carriers is considered through the Poisson equation. An analytically non-solvable differential equation system is consequently set-up. With numerical approaches, valid solutions describing the macroscopic processes in organic solar cells can be found. An additional optical simulation is used to determine the spatially resolved charge carrier generation rates due to interference.
Concepts regarding organic semiconductors and solar cells are introduced in the first part of this work. All chapters are based on previous ones and logically outline the basic physics, device architectures, models of charge carrier generation and recombination as well as the mathematic and numerical approaches to obtain valid simulation results.
In the second part, the simulation is used to elaborate issues of current interest in organic solar cell research. This includes a basic understanding of how the open circuit voltage is generated and which processes limit its value. S-shaped current-voltage characteristics are explained assigning finite surface recombination velocities at metal electrodes piling-up local space charges. The power conversion efficiency is identified as a trade-off between charge carrier accumulation and charge extraction. This leads to an optimum of the power conversion efficiency at moderate to high charge carrier mobilities. Differences between recombination rates determined by different interpretations of identical experimental results are assigned to a spatially inhomogeneous recombination, relevant for almost all low mobility semiconductor devices.
The present work addressed the influence of spins on fundamental processes in organic
semiconductors. In most cases, the role of spins in the conversion of sun light
into electricity was of particular interest. However, also the reversed process, an electric
current creating luminescence, was investigated by means of spin sensitive measurements.
In this work, many material systems were probed with a variety of innovative
detection techniques based on electron paramagnetic resonance spectroscopy.
More precisely, the observable could be customized which resulted in the experimental
techniques photoluminescence detected magnetic resonance (PLDMR), electrically
detected magnetic resonance (EDMR), and electroluminescence detected magnetic
resonance (ELDMR). Besides the commonly used continuous wave EPR spectroscopy,
this selection of measurement methods yielded an access to almost all intermediate
steps occurring in organic semiconductors during the conversion of light into electricity
and vice versa. Special attention was paid to the fact that all results were applicable
to realistic working conditions of the investigated devices, i.e. room temperature application and realistic illumination conditions.
In this work, a bridge was built between the so-far separate fields of spin defects and 2D systems: for the first time, an optically addressable spin defect (VB-) in a van der Waals material (hexagonal boron nitride) was identified and exploited. The results of this thesis are divided into three topics as follows:
1.) Identification of VB-:
In the scope of this chapter, the defect ,the negatively charged boron vacancy VB-, is identified and characterized. An initialization and readout of the spin state can be demonstrated optically at room temperature and its spin Hamiltonian contributions can be quantified.
2.) Coherent Control of VB-:
A coherent control is required for the defect to be utilized for quantum applications, which