Estudo de camadas transportadoras de cargas em diodos emissores de luz poliméricos. / Study of charge transport layers in polymer light emitting diodes.

Santos, João Claudio de Brito

20 April 2007

No presente trabalho foi realizado o estudo das propriedades ópticas e elétricas de dispositivos eletroluminescentes poliméricos, conhecidos como diodos emissores de luz poliméricos (PLEDs), e o desenvolvimento de camadas transportadoras de carga (HTL), que visam promover um aumento da eficiência elétrica dos dispositivos. Para o estudo das propriedades ópticas e elétricas dos PLEDs, foram fabricados dispositivos com estruturas do tipo Ânodo/HTL/Polímero Eletroluminescente/Cátodo. Foram apresentadas todas as etapas de fabricação dos dispositivos, assim como seus processos de caracterização. Para o ânodo, foi utilizado um óxido transparente condutor, óxido de índio-estanho - ITO, com tratamento superficial em plasma de oxigênio. Foram estudados três materiais diferentes para as HTLs. Filmes de PAni:PVS ou PAni:Ni-TS-Pc foram depositados pela técnica de automontagem (Layer-by-Layer) e os filmes de PEDOT:PSS foram depositados pelo método de spin-coating. O polímero eletroluminescente utilizado neste trabalho foi o MEH-PPV, também depositado pelo método de spin-coating. Para o cátodo foi utilizado o alumínio, evaporado termicamente. O encapsulamento dos dispositivos foi realizado em atmosfera inerte de argônio para diminuir os efeitos de degradação através do oxigênio e da luz. O emprego de camadas transportadoras de buracos (HTLs) resultou numa sensível diminuição no valor da tensão de operação dos dispositivos, quando empregados filmes de PAni:PVS e PAni:Ni-TS-Pc. Os valores das tensões de operação baixaram de 12 V para cerca de 3 V em relação aos dispositivos fabricados sem a utilização de HTLs. Através da microscopia de força atômica, foi possível determinar a espessura das bicamadas e a rugosidade superficial dos filmes de PAni:PVS para correlacionar estes resultados com a resposta elétrica dos dispositivos. Espessuras de 4nm (para 1 bicamada) resultaram em tensões de operação de 3 V. Foi possível verificar também, por espectroscopia no UV-VIS, que este tipo de filme absorve luz em freqüência diferente daquela emitida pelo MEH-PPV. Medidas elétricas em regime de corrente contínua, curvas de Corrente vs. Tensão e, em regime de corrente alternada, espectroscopia de impedância, foram realizadas em dispositivos para determinar o valor da tensão de operação e estudar os efeitos de interface nas diferentes camadas que compõe um dispositivo. Através das curvas obtidas pela espectroscopia de impedância, foi possível determinar os valores dos componentes dos circuitos equivalentes (capacitores e resistores). Com isso, é possível simular o comportamento destes dispositivos através de circuitos elétricos antes mesmo de serem fabricados. Pelos resultados obtidos, todas as HTLs estudadas contribuíram para uma sensível diminuição no valor da tensão de operação dos dispositivos, apontando-os como excelentes materiais a serem utilizados com o objetivo de alcançar uma maior eficiência e um melhor desempenho destes dispositivos. / In the present work, the study of the optical and electrical properties of polymeric electroluminescent devices known as Polymer Light-Emitting Diodes (PLEDs) and the development of Hole Transport Layers (HTLs) to promote an increase of the electrical efficiency of the devices was performed. PLEDs were constructed with structures like Anode/HTL/Electroluminescent Polymer/Cathode in order to study the optical and electrical properties of these devices. All the stages of the devices production were presented, as well as its characterization processes. For the anode a conductive transparent oxide (Indium Tin Oxide - ITO) with a superficial oxygen plasma treatment was used. Three different materials for the HTLs were used. Films of PAni:PVS or PAni:Ni-TS-Pc were deposited by the self-assembly technique (Layer-by-Layer) and the films of PEDOT:PSS were deposited by the spin-coating method. The electroluminescent polymer used in this work was MEH-PPV, also deposited by the spin-coating method. Aluminum was deposited by thermal evaporation for the cathode. The devices encapsulation was performed in Argon inert atmosphere to reduce the degradation effects through oxygen and light. The use of Hole Transport Layers (HTLs) resulted in a sensitive decrease in the devices operating voltage value when films of PAni:PVS and PAni:Ni-TS-Pc were used. The operating voltage values have decreased from 12 V to 3 V in relation to the devices assembled without the usage of HTLs. By the use of Atomic Force Microscopy measurements the thickness of the bilayers and the surface roughness of the PAni:PVS films was obtained to correlate these results with the devices electric characteristics. Thicknesses of 3 to 4 nm (for one bilayer) resulted in operating voltage of 3 V. It was possible to verify also, by UVVIS Spectroscopy, that this type of PAni:PVS films absorbs light in a different frequency than that emitted by MEH-PPV. Electric measurements in the direct current, Current vs. Voltage curves and, in alternating current, Impedance Spectroscopy, were performed in devices to determine the operating voltage value and to study the interface effects in the different layers used in the devices. Analyzing the curves obtained by the impedance spectroscopy, it was possible to determine the values of the equivalent circuit components (capacitors and resistors) and, with that, to simulate the behavior of these devices through electric circuits even before they were manufactured. By the experimental results, all the HTLs studied have contributed to a sensitive decrease in the devices operating voltage, indicating them as excellent materials to be used to reach a higher efficiency and a better performance of these devices.

Camadas transportadoras de buracos

Caracterização elétrica

Dispositivos eletrônicos

Electrical characterization

Electrical measures

Electronic devices

Espectroscopia de impedância

Filmes finos (propriedades elétricas)

Hole transport layers

Impedance spectroscopy

LEDs poliméricos

Medidas elétricas

Polímeros (materiais)

Polymer LEDs

Polymers (materials)

Thin films (electrical properties)

Estudo de camadas transportadoras de cargas em diodos emissores de luz poliméricos. / Study of charge transport layers in polymer light emitting diodes.

João Claudio de Brito Santos

20 April 2007

No presente trabalho foi realizado o estudo das propriedades ópticas e elétricas de dispositivos eletroluminescentes poliméricos, conhecidos como diodos emissores de luz poliméricos (PLEDs), e o desenvolvimento de camadas transportadoras de carga (HTL), que visam promover um aumento da eficiência elétrica dos dispositivos. Para o estudo das propriedades ópticas e elétricas dos PLEDs, foram fabricados dispositivos com estruturas do tipo Ânodo/HTL/Polímero Eletroluminescente/Cátodo. Foram apresentadas todas as etapas de fabricação dos dispositivos, assim como seus processos de caracterização. Para o ânodo, foi utilizado um óxido transparente condutor, óxido de índio-estanho - ITO, com tratamento superficial em plasma de oxigênio. Foram estudados três materiais diferentes para as HTLs. Filmes de PAni:PVS ou PAni:Ni-TS-Pc foram depositados pela técnica de automontagem (Layer-by-Layer) e os filmes de PEDOT:PSS foram depositados pelo método de spin-coating. O polímero eletroluminescente utilizado neste trabalho foi o MEH-PPV, também depositado pelo método de spin-coating. Para o cátodo foi utilizado o alumínio, evaporado termicamente. O encapsulamento dos dispositivos foi realizado em atmosfera inerte de argônio para diminuir os efeitos de degradação através do oxigênio e da luz. O emprego de camadas transportadoras de buracos (HTLs) resultou numa sensível diminuição no valor da tensão de operação dos dispositivos, quando empregados filmes de PAni:PVS e PAni:Ni-TS-Pc. Os valores das tensões de operação baixaram de 12 V para cerca de 3 V em relação aos dispositivos fabricados sem a utilização de HTLs. Através da microscopia de força atômica, foi possível determinar a espessura das bicamadas e a rugosidade superficial dos filmes de PAni:PVS para correlacionar estes resultados com a resposta elétrica dos dispositivos. Espessuras de 4nm (para 1 bicamada) resultaram em tensões de operação de 3 V. Foi possível verificar também, por espectroscopia no UV-VIS, que este tipo de filme absorve luz em freqüência diferente daquela emitida pelo MEH-PPV. Medidas elétricas em regime de corrente contínua, curvas de Corrente vs. Tensão e, em regime de corrente alternada, espectroscopia de impedância, foram realizadas em dispositivos para determinar o valor da tensão de operação e estudar os efeitos de interface nas diferentes camadas que compõe um dispositivo. Através das curvas obtidas pela espectroscopia de impedância, foi possível determinar os valores dos componentes dos circuitos equivalentes (capacitores e resistores). Com isso, é possível simular o comportamento destes dispositivos através de circuitos elétricos antes mesmo de serem fabricados. Pelos resultados obtidos, todas as HTLs estudadas contribuíram para uma sensível diminuição no valor da tensão de operação dos dispositivos, apontando-os como excelentes materiais a serem utilizados com o objetivo de alcançar uma maior eficiência e um melhor desempenho destes dispositivos. / In the present work, the study of the optical and electrical properties of polymeric electroluminescent devices known as Polymer Light-Emitting Diodes (PLEDs) and the development of Hole Transport Layers (HTLs) to promote an increase of the electrical efficiency of the devices was performed. PLEDs were constructed with structures like Anode/HTL/Electroluminescent Polymer/Cathode in order to study the optical and electrical properties of these devices. All the stages of the devices production were presented, as well as its characterization processes. For the anode a conductive transparent oxide (Indium Tin Oxide - ITO) with a superficial oxygen plasma treatment was used. Three different materials for the HTLs were used. Films of PAni:PVS or PAni:Ni-TS-Pc were deposited by the self-assembly technique (Layer-by-Layer) and the films of PEDOT:PSS were deposited by the spin-coating method. The electroluminescent polymer used in this work was MEH-PPV, also deposited by the spin-coating method. Aluminum was deposited by thermal evaporation for the cathode. The devices encapsulation was performed in Argon inert atmosphere to reduce the degradation effects through oxygen and light. The use of Hole Transport Layers (HTLs) resulted in a sensitive decrease in the devices operating voltage value when films of PAni:PVS and PAni:Ni-TS-Pc were used. The operating voltage values have decreased from 12 V to 3 V in relation to the devices assembled without the usage of HTLs. By the use of Atomic Force Microscopy measurements the thickness of the bilayers and the surface roughness of the PAni:PVS films was obtained to correlate these results with the devices electric characteristics. Thicknesses of 3 to 4 nm (for one bilayer) resulted in operating voltage of 3 V. It was possible to verify also, by UVVIS Spectroscopy, that this type of PAni:PVS films absorbs light in a different frequency than that emitted by MEH-PPV. Electric measurements in the direct current, Current vs. Voltage curves and, in alternating current, Impedance Spectroscopy, were performed in devices to determine the operating voltage value and to study the interface effects in the different layers used in the devices. Analyzing the curves obtained by the impedance spectroscopy, it was possible to determine the values of the equivalent circuit components (capacitors and resistors) and, with that, to simulate the behavior of these devices through electric circuits even before they were manufactured. By the experimental results, all the HTLs studied have contributed to a sensitive decrease in the devices operating voltage, indicating them as excellent materials to be used to reach a higher efficiency and a better performance of these devices.

Camadas transportadoras de buracos

Caracterização elétrica

Dispositivos eletrônicos

Espectroscopia de impedância

Filmes finos (propriedades elétricas)

LEDs poliméricos

Medidas elétricas

Polímeros (materiais)

Electrical characterization

Electrical measures

Electronic devices

Hole transport layers

Impedance spectroscopy

Polymer LEDs

Polymers (materials)

Thin films (electrical properties)

Thienoacene dimers based on the thieno[3,2-b] thiophene moiety: synthesis, characterization and electronic properties

Niebel, Claude, Kim, Yeongin, Ruzié, Christian, Karpinska, Jolanta, Chattopadhyay, Basab, Schweicher, Guillaume, Richard, Audrey, Lemaur, Vincent, Olivier, Yoann, Cornil, Jérôme, Kennedy, Alan R., Diao, Ying, Lee, Wen-Ya, Mannsfeld, Stefan, Bao, Zhenan, Geerts, Yves H.

09 January 2020

Two thienoacene dimers based on the thieno[3,2-b]thiophene moiety were efficiently synthesized, characterized and evaluated as active hole-transporting layers in organic thin-film field-effect transistors. Both compounds behaved as active p-channel organic semi-conductors showing averaged hole mobility of up to 1.33 cm² V⁻¹ s⁻¹.

info:eu-repo/classification/ddc/540

ddc:540

info:eu-repo/classification/ddc/620

ddc:620

info:eu-repo/classification/ddc/530

ddc:530

Interaction électron-phonon dans le cadre du formalisme des fonctions de Green hors-équilibre : application à la modélisation de transistors MOS de type p / Electron-phonon interactions within the quantum formalism of Nonequilibrium Green’s Function applied to the simulation of p-type MOSFETs

Dib, Elias

19 December 2013

Depuis que les dimensions des nano-dispositifs ont atteint l’échelle nanométrique, la simulation quantique est devenue incontournable dans le domaine de la nanoélectronique. Parmi les différents phénomènes physiques, l’interaction électron-phonon représente un processus majeur limitant la mobilité des porteurs de charge à température ambiante. En combinant la théorie multibandes k.p avec le formalisme quantique des fonctions de Green hors-équilibre, nous avons étudié et comparé deux types de dispositifs double-grille dopés p: le transistor MOS «conventionnel» et celui dit «sans jonction». L’influence de l’orientation cristalline, du matériau semi-conducteur, de la longueur de grille et de l’épaisseur du substrat a été étudiée afin d’optimiser les performances de ces dispositifs aux dimensions ultimes. D’un point de vue plus fondamental, l’interaction avec les phonons est habituellement implémentée à partir de l’approche auto-cohérente de Born (SCBA). Nous avons exploré la validité des approches non auto-cohérentes numériquement moins coûteuse qui conservent le courant : Lowest Order Approximation (LOA). Une comparaison entre SCBA, LOA et son prolongement analytique (LOA+AC) en modèle multi-bande a été menée. / Device simulation has attracted large interest since the dimensions of electronic devices reached the nanoscale. Among the new physical phenomena observed we focus on interaction-induced effects. Particular emphasis is placed on electron-phonon interactions as it is one of the most important carrier mobility-limiting mechanisms in nanodevices. Using the k.p multiband theory combined with the Non-Equilibrium Green's Function formalism, we model 2 types of double-gate devices: p-type MOSFETs and junctionless p-type MOSFETs. The 2D architecture of the double-gate device enables us to investigate the influence of confinement in one direction, infinite propagation in the other direction and connection to semi-infinite reservoirs in the last one. Different crystallographic orientation, channel materials, gate lengths and channel widths are investigated. From a fundamental point of view, phonon scattering is usually implement via the so-called Self-Consistent Born Approximation (SCBA°. We explore the validity of a one shot current conserving method based on the Lowest Order Approximation (LOA). A comparison between SCBA, LOA and its analytic continuation (LOA+AC) in multiband models is discussed.

Modèle k.p

Fonction de Green hors-équilibre

Simulation de transistor type p

Transistor sans jonction

Phonon

Interaction électron-phonon

K.p model

Nonequilibrium Green's Function

NEGF

Simulation of p-type transistor

Junctionless transistor

Phonon

Electron-phonon interaction

Hole transport in valence band

Hole Transport Materials for Solid-State Mesoscopic Solar Cells

Yang, Lei

January 2014

The solid-state mesoscopic solar cells (sMSCs) have been developed as a promising alternative technology to the conventional photovoltaics. However, the device performance suffers from the low hole-mobilities and the incomplete pore filling of the hole transport materials (HTMs) into the mesoporous electrodes. A variety of HTMs and different preparation methods have been studied to overcome these limitations. There are two types of sMSCs included in this doctoral thesis, namely solid-state dye-sensitized solar cells (sDSCs) and organometallic halide perovskite based solar cells. Two different types of HTMs, namely the small molecule organic HTM spiro-OMeTAD and the conjugated polymer HTM P3HT, were compared in sDSCs. The photo-induced absorption spectroscopy (PIA) spectra and spectroelectrochemical data suggested that the dye-dye hole conduction occurs in the absence of HTM and appears to be of significant importance to the contribution of hole transport. The PIA measurements and transient absorption spectroscopy (TAS) indicated that the oxidized dye was efficiently regenerated by a small molecule organic HTM TPAA due to its excellent pore filling. The conducting polymer P3HT was employed as a co-HTM to transfer the holes away from TPAA to prohibit the charge carrier recombination and to improve the hole transport. An alternative small molecule organic HTM, MeO-TPD, was found to outperform spiro-OMeTAD in sDSCs due to its more efficient pore filling and higher hole-mobility. Moreover, an initial light soaking treatment was observed to significantly improve the device performance due to a mechanism of Li+ ion migration towards the TiO2 surface. In order to overcome the infiltration difficulty of conducting polymer HTMs, a state-of-the-art method to perform in-situ photoelectrochemical polymerization (PEP) in an aqueous micellar solution of bis-EDOT monomer was developed as an environmental-friendly alternative pathway with scale-up potential for constructing efficient sDSCs with polymer HTMs. Three different types of HTMs, namely DEH, spiro-OMeTAD and P3HT, were used to investigate the influence of HTMs on the charge recombination in CH3NH3PbI3 perovskite based sMSCs. The photovoltage decay measurements indicate that the electron lifetime (τn) of these devices decreases by one order of magnitude in the sequence τspiro-OMeTAD > τP3HT > τDEH.

mesoscopic solar cells

solid-state dye-sensitized solar cells

organometallic halide perovskite

hole transport materials

mesoporous TiO2

conjugated polymer

sensitizer

transient absorption spectroscopy

photo-induced absorption spectroscopy

spiro-OMeTAD

P3HT

TPAA

MeO-TPD

bis-EDOT

DEH

Li+ ion migration

charge recombination

electron lifetime

Design and theoretical study of Wurtzite III-N deep ultraviolet edge emitting laser diodes

Satter, Md. Mahbub

12 January 2015

Designs for deep ultraviolet (DUV) edge emitting laser diodes (LDs) based on the wurtzite III-nitride (III-N) material system are presented. A combination of proprietary and commercial advanced semiconductor LD simulation software is used to study the operation of III-N based DUV LDs theoretically. Critical factors limiting device performance are identified based on an extensive literature survey. A comprehensive design parameter space is investigated thoroughly with the help of advanced scripting capabilities. Several design strategies are proposed to eliminate the critical problems completely or partially. A DUV LD design is proposed based exclusively on AlInN active layers grown epitaxially on bulk AlN substrates because AlInN offers a promising alternative to AlGaN for the realization of LDs and LEDs operating in the DUV regime. The proposed AlInN-based design also features a tapered electron blocking layer (EBL) instead of a homogeneous one. Tapered EBLs redistribute the interfacial polarization charge volumetrically throughout the entire EBL thickness via compositional grading, and eliminate the parasitic inversion layer charge. AlGaN based DUV LD designs are explored also because at present, it may be difficult to grow AlInN epitaxially with superior crystalline quality. Polarization charge matching is proposed to improve electron and hole wavefunction overlap within the active region. Although the strategy of polarization charge matching has already been proposed in the literature to enhance performance of visible wavelength LEDs and LDs, the proposed design presents the first demonstration that polarization charge matching is also feasible for DUV LDs operating at sub-300 nm wavelengths. A lateral current injection (LCI) LD design is proposed featuring polarization-charge-matched barriers and regrown Ohmic contacts to avoid a group of issues related to the highly inefficient p-type doping of wide bandgap III-N materials in vertical injection designs. The proposed design partially decouples the problem of electrical injection from that of optical confinement. Although the idea of an LCI LD design has been proposed in the literature in the 90s to be used as longer wavelength active sources in optoelectronic integrated circuits using GaInAsP/InP and related material systems, the proposed design is the first theoretical demonstration that this concept can be applied to DUV LDs based on III-N material system. To solve the problem of hole transport in vertical injection designs, a DUV LD design based exclusively on AlGaN material system is presented, featuring an inverse-tapered p-waveguide layer instead of an EBL. Several EBL designs are investigated, and compared with conventionally-tapered EBL design. Through judicious volumetric redistribution of fixed negative polarization charge, inverse tapering may be exploited to achieve nearly flat valence band profiles free from barriers to hole injection into the active region, in contrast to conventional designs. Numerical simulations demonstrate that the inverse tapered strategy is a viable solution for efficient hole injection in vertical injection DUV LDs operating at shorter wavelengths (< 290 nm).

AlInN active layer

AlGaN active layer

AlGaN epitaxial layer

AlN substrate

Quantum-confined Stark effect

Tapered electron blocking layer

Lateral current injection

Quaternary barrier

Regrown Ohmic contacts

Deep ultraviolet laser diodes

Efficient hole transport

Hole blocking layer

Inverse tapering

Optical absorption loss

Polarization charge

Charge transport and energy levels in organic semiconductors / Ladungstransport und Energieniveaus in organischen Halbleitern

Widmer, Johannes

25 November 2014

Organic semiconductors are a new key technology for large-area and flexible thin-film electronics. They are deposited as thin films (sub-nanometer to micrometer) on large-area substrates. The technologically most advanced applications are organic light emitting diodes (OLEDs) and organic photovoltaics (OPV). For the improvement of performance and efficiency, correct modeling of the electronic processes in the devices is essential. Reliable characterization and validation of the electronic properties of the materials is simultaneously required for the successful optimization of devices. Furthermore, understanding the relations between material structures and their key characteristics opens the path for innovative material and device design. In this thesis, two material characterization methods are developed, respectively refined and applied: a novel technique for measuring the charge carrier mobility μ and a way to determine the ionization energy IE or the electron affinity EA of an organic semiconductor. For the mobility measurements, a new evaluation approach for space-charge limited current (SCLC) measurements in single carrier devices is developed. It is based on a layer thickness variation of the material under investigation. In the \"potential mapping\" (POEM) approach, the voltage as a function of the device thickness V(d) at a given current density is shown to coincide with the spatial distribution of the electric potential V(x) in the thickest device. On this basis, the mobility is directly obtained as function of the electric field F and the charge carrier density n. The evaluation is model-free, i.e. a model for μ(F, n) to fit the measurement data is not required, and the measurement is independent of a possible injection barrier or potential drop at non-optimal contacts. The obtained μ(F, n) function describes the effective average mobility of free and trapped charge carriers. This approach realistically describes charge transport in energetically disordered materials, where a clear differentiation between trapped and free charges is impossible or arbitrary. The measurement of IE and EA is performed by characterizing solar cells at varying temperature T. In suitably designed devices based on a bulk heterojunction (BHJ), the open-circuit voltage Voc is a linear function of T with negative slope in the whole measured range down to 180K. The extrapolation to temperature zero V0 = Voc(T → 0K) is confirmed to equal the effective gap Egeff, i.e. the difference between the EA of the acceptor and the IE of the donor. The successive variation of different components of the devices and testing their influence on V0 verifies the relation V0 = Egeff. On this basis, the IE or EA of a material can be determined in a BHJ with a material where the complementary value is known. The measurement is applied to a number of material combinations, confirming, refining, and complementing previously reported values from ultraviolet photo electron spectroscopy (UPS) and inverse photo electron spectroscopy (IPES). These measurements are applied to small molecule organic semiconductors, including mixed layers. In blends of zinc-phthalocyanine (ZnPc) and C60, the hole mobility is found to be thermally and field activated, as well as increasing with charge density. Varying the mixing ratio, the hole mobility is found to increase with increasing ZnPc content, while the effective gap stays unchanged. A number of further materials and material blends are characterized with respect to hole and electron mobility and the effective gap, including highly diluted donor blends, which have been little investigated before. In all materials, a pronounced field activation of the mobility is observed. The results enable an improved detailed description of the working principle of organic solar cells and support the future design of highly efficient and optimized devices. / Organische Halbleiter sind eine neue Schlüsseltechnologie für großflächige und flexible Dünnschichtelektronik. Sie werden als dünne Materialschichten (Sub-Nanometer bis Mikrometer) auf großflächige Substrate aufgebracht. Die technologisch am weitesten fortgeschrittenen Anwendungen sind organische Leuchtdioden (OLEDs) und organische Photovoltaik (OPV). Zur weiteren Steigerung von Leistungsfähigkeit und Effizienz ist die genaue Modellierung elektronischer Prozesse in den Bauteilen von grundlegender Bedeutung. Für die erfolgreiche Optimierung von Bauteilen ist eine zuverlässige Charakterisierung und Validierung der elektronischen Materialeigenschaften gleichermaßen erforderlich. Außerdem eröffnet das Verständnis der Zusammenhänge zwischen Materialstruktur und -eigenschaften einen Weg für innovative Material- und Bauteilentwicklung. Im Rahmen dieser Dissertation werden zwei Methoden für die Materialcharakterisierung entwickelt, verfeinert und angewandt: eine neuartige Methode zur Messung der Ladungsträgerbeweglichkeit μ und eine Möglichkeit zur Bestimmung der Ionisierungsenergie IE oder der Elektronenaffinität EA eines organischen Halbleiters. Für die Beweglichkeitsmessungen wird eine neue Auswertungsmethode für raumladungsbegrenzte Ströme (SCLC) in unipolaren Bauteilen entwickelt. Sie basiert auf einer Schichtdickenvariation des zu charakterisierenden Materials. In einem Ansatz zur räumlichen Abbildung des elektrischen Potentials (\"potential mapping\", POEM) wird gezeigt, dass das elektrische Potential als Funktion der Schichtdicke V(d) bei einer gegebenen Stromdichte dem räumlichen Verlauf des elektrischen Potentials V(x) im dicksten Bauteil entspricht. Daraus kann die Beweglichkeit als Funktion des elektrischen Felds F und der Ladungsträgerdichte n berechnet werden. Die Auswertung ist modellfrei, d.h. ein Modell zum Angleichen der Messdaten ist für die Berechnung von μ(F, n) nicht erforderlich. Die Messung ist außerdem unabhängig von einer möglichen Injektionsbarriere oder einer Potentialstufe an nicht-idealen Kontakten. Die gemessene Funktion μ(F, n) beschreibt die effektive durchschnittliche Beweglichkeit aller freien und in Fallenzuständen gefangenen Ladungsträger. Dieser Zugang beschreibt den Ladungstransport in energetisch ungeordneten Materialien realistisch, wo eine klare Unterscheidung zwischen freien und Fallenzuständen nicht möglich oder willkürlich ist. Die Messung von IE und EA wird mithilfe temperaturabhängiger Messungen an Solarzellen durchgeführt. In geeigneten Bauteilen mit einem Mischschicht-Heteroübergang (\"bulk heterojunction\" BHJ) ist die Leerlaufspannung Voc im gesamten Messbereich oberhalb 180K eine linear fallende Funktion der Temperatur T. Es kann bestätigt werden, dass die Extrapolation zum Temperaturnullpunkt V0 = Voc(T → 0K) mit der effektiven Energielücke Egeff , d.h. der Differenz zwischen EA des Akzeptor-Materials und IE des Donator-Materials, übereinstimmt. Die systematische schrittweise Variation einzelner Bestandteile der Solarzellen und die Überprüfung des Einflusses auf V0 bestätigen die Beziehung V0 = Egeff. Damit kann die IE oder EA eines Materials bestimmt werden, indem man es in einem BHJ mit einem Material kombiniert, dessen komplementärer Wert bekannt ist. Messungen per Ultraviolett-Photoelektronenspektroskopie (UPS) und inverser Photoelektronenspektroskopie (IPES) werden damit bestätigt, präzisiert und ergänzt. Die beiden entwickelten Messmethoden werden auf organische Halbleiter aus kleinen Molekülen einschließlich Mischschichten angewandt. In Mischschichten aus Zink-Phthalocyanin (ZnPc) und C60 wird eine Löcherbeweglichkeit gemessen, die sowohl thermisch als auch feld- und ladungsträgerdichteaktiviert ist. Wenn das Mischverhältnis variiert wird, steigt die Löcherbeweglichkeit mit zunehmendem ZnPc-Anteil, während die effektive Energielücke unverändert bleibt. Verschiedene weitere Materialien und Materialmischungen werden hinsichtlich Löcher- und Elektronenbeweglichkeit sowie ihrer Energielücke charakterisiert, einschließlich bisher wenig untersuchter hochverdünnter Donator-Systeme. In allen Materialien wird eine deutliche Feldaktivierung der Beweglichkeit beobachtet. Die Ergebnisse ermöglichen eine verbesserte Beschreibung der detaillierten Funktionsweise organischer Solarzellen und unterstützen die künftige Entwicklung hocheffizienter und optimierter Bauteile.

Physik

Festkörperphysik

Festkörper-Physik

Halbleiterphysik

Halbleiter-Physik

Organische Halbleiter

Organische Elektronik

Organische Solarzellen

Organische Photovoltaik

Organische Moleküle

Kleine Moleküle

Molekulare Elektronik

Molekulare Halbleiter

Amorphe Halbleiter

Ladungstransport

Ladungsbeweglichkeit

Ladungs-Beweglichkeit

Ladungsmobilität

Ladungs-Mobilität

Ladungsträgerbewegleichkeit

Ladungsträger-Beweglichkeit

Ladungsträgermobilität

Ladungsträger-Mobilität

Elektronenbeweglichkeit

Elektronen-Beweglichkeit

Elektronenmobilität

Elektronen-Mobilität

Löcherbeweglichkeit

Löcher-Beweglichkeit

Löchermobilität

Löcher-Mobilität

Raumladungsbegrenzte Ströme

Raumladungsbegrenzter Strom

Unipolare Bauteile

Unipolares Bauteil

Löchertransport

Löcher-Transport

Löcherleitfähigkeit

Löcher-Leitfähigkeit

Löcherleitung

Elektronentransport

Elektronen-Transport

Elektronenleitfähigkeit

Elektronen-Leitfähigkeit

Elektronenleitung

Hüpftransport

Hüpf-Transport

Poole-Frenkel-Transport

Feldaktivierung

Feld-Aktivierung

Dichteaktivierung

Dichte-Aktivierung

Ladungsdichteaktivierung

Ladungsdichte-Aktivierung

Ladungsträgerdichteaktivierung

Ladungsträgerdichte-Aktivierung

Ladungsträger-Dichteaktivierung

Ladungsträger-Dichte-Aktivierung

Drifttransport

Drift-Transport

Temperaturaktivierung

Temperatur-Aktivierung

Ionisationsenergie

Ionisations-Energie

Ionisationspotential

Ionisationspotenzial

Ionisations-Potential

Ionisations-Potenzial

Elektronenaffinität

Elektronen-Affinität

Leitungsband

Leitungs-Band

Valenzband

Valenz-Band

Höchstes besetztes Molekülorbital

Höchstes besetztes Molekül-Orbital

Niedrigstes unbesetztes Molekülorbital

Niedrigstes unbesetztes Molekül-Orbital

Transportniveau

Transport-Niveau

Energieniveaus

Energie-Niveaus

Donator

Akzeptor

Donator-Akzeptor

Effektive Lücke

Effektive Bandlücke

Bandlücke

Energielücke

Effektive Energielücke

Mischschichtheteroübergang

Mischschicht-Heteroübergang

Flacher Heteroübergang

Planarer Heteroübergang

Dotierung

Dotierte Transportschichten

Dotierte Transport-Schichten

Injektionsbarriere

Injektions-Barriere

Extraktionsbarriere

Extraktions-Barriere

Diffusion

Ladungsdiffusion

Ladungs-Diffusion

Ladungsträgerdiffusion

Ladungsträger-Diffusion

Bandverbiegung

Band-Verbiegung

Dünnschichtelektronik

Dünnschicht-Elektronik

Physics

Solid State Physics

Semiconductor Physics

Organic Semiconductors

Organic Electronics

Organic Solar Cells

Organic Photovoltaics

Organic Molecules

Small Molecules

Molecular Electronics

Molecular Semiconductors

Amorphous Semiconductors

Charge Transport

Charge Mobility

Charge Carrier Mobility

Electron Mobility

Hole Mobility

Space-Charge Limited Current

SCLC

Single Carrier Devices

Hole-Only Devices

Hole Conduction

Hole Conductivity

Hole Transport

Electron-Only Devices

Electron Conduction

Electron Conductivity

Electron Transport

Hopping Transport

Poole-Frenkel Transport

Field Activation

Density Activation

Charge Density Activation

Charge Carrier Density Activation

Drift Transport

Temperature Activation

Ionization Energy

Ionization Potential

Electron Affinity

Conduction Band

Valence Band

Highest Occupied Molecular Orbital

HOMO

Lowest Unoccupied Molecular Orbital

LUMO

Transport Level

Energy Levels

Donor

Acceptor

Donor-Acceptor

Effective Gap

Effective Band Gap

Band Gap

Energy Gap

Effective Energy Gap

Bulk Heterojunction

BHJ

Flat Heterojunction

FHJ

Planar Heterojunction

PHJ

Doping

Doped Transport Layers

Injection Barrier

Extraction Barrier

Diffusion

Charge Diffusion

Charge Carrier Diffusion

Band Bending

Thin Film Electronics

ddc:530

rvk:UP 3130

Elektronik

Polymerelektronik

Halbleiterelektronik

Festkörperelektronik

Physik

Angewandte Physik

Festkörperphysik

Amorpher Halbleiter

p-Halbleiter

n-Halbleiter

Metall-Halbleiter-Kontakt

Intrinsischer Halbleiter

Dotierter Halbleiter

Organischer Halbleiter

Halbleiterschicht

Ohm-Kontakt

Organisches Halbleiterbauelement

Fullerene

Buckminsterfulleren

Hopping-Leitfähigkeit

Elektrische Leitfähigkeit

Leitfähigkeit

Dunkelleitfähigkeit

Elektronenleitung

Beweglichkeit <Physik>

Ladungsträgerbeweglichkeit

Elektronenbeweglichkeit

Ionisationsenergie

Elektronenaffinität

Charge transport and energy levels in organic semiconductors

Widmer, Johannes

02 October 2014

Organic semiconductors are a new key technology for large-area and flexible thin-film electronics. They are deposited as thin films (sub-nanometer to micrometer) on large-area substrates. The technologically most advanced applications are organic light emitting diodes (OLEDs) and organic photovoltaics (OPV). For the improvement of performance and efficiency, correct modeling of the electronic processes in the devices is essential. Reliable characterization and validation of the electronic properties of the materials is simultaneously required for the successful optimization of devices. Furthermore, understanding the relations between material structures and their key characteristics opens the path for innovative material and device design. In this thesis, two material characterization methods are developed, respectively refined and applied: a novel technique for measuring the charge carrier mobility μ and a way to determine the ionization energy IE or the electron affinity EA of an organic semiconductor. For the mobility measurements, a new evaluation approach for space-charge limited current (SCLC) measurements in single carrier devices is developed. It is based on a layer thickness variation of the material under investigation. In the \"potential mapping\" (POEM) approach, the voltage as a function of the device thickness V(d) at a given current density is shown to coincide with the spatial distribution of the electric potential V(x) in the thickest device. On this basis, the mobility is directly obtained as function of the electric field F and the charge carrier density n. The evaluation is model-free, i.e. a model for μ(F, n) to fit the measurement data is not required, and the measurement is independent of a possible injection barrier or potential drop at non-optimal contacts. The obtained μ(F, n) function describes the effective average mobility of free and trapped charge carriers. This approach realistically describes charge transport in energetically disordered materials, where a clear differentiation between trapped and free charges is impossible or arbitrary. The measurement of IE and EA is performed by characterizing solar cells at varying temperature T. In suitably designed devices based on a bulk heterojunction (BHJ), the open-circuit voltage Voc is a linear function of T with negative slope in the whole measured range down to 180K. The extrapolation to temperature zero V0 = Voc(T → 0K) is confirmed to equal the effective gap Egeff, i.e. the difference between the EA of the acceptor and the IE of the donor. The successive variation of different components of the devices and testing their influence on V0 verifies the relation V0 = Egeff. On this basis, the IE or EA of a material can be determined in a BHJ with a material where the complementary value is known. The measurement is applied to a number of material combinations, confirming, refining, and complementing previously reported values from ultraviolet photo electron spectroscopy (UPS) and inverse photo electron spectroscopy (IPES). These measurements are applied to small molecule organic semiconductors, including mixed layers. In blends of zinc-phthalocyanine (ZnPc) and C60, the hole mobility is found to be thermally and field activated, as well as increasing with charge density. Varying the mixing ratio, the hole mobility is found to increase with increasing ZnPc content, while the effective gap stays unchanged. A number of further materials and material blends are characterized with respect to hole and electron mobility and the effective gap, including highly diluted donor blends, which have been little investigated before. In all materials, a pronounced field activation of the mobility is observed. The results enable an improved detailed description of the working principle of organic solar cells and support the future design of highly efficient and optimized devices.:1. Introduction 2. Organic semiconductors and devices 2.1. Organic semiconductors 2.1.1. Conjugated π system 2.1.2. Small molecules and polymers 2.1.3. Disorder in amorphous materials 2.1.4. Polarons 2.1.5. Polaron hopping 2.1.6. Fermi-Dirac distribution and Fermi level 2.1.7. Quasi-Fermi levels 2.1.8. Trap states 2.1.9. Doping 2.1.10. Excitons 2.2. Interfaces and blend layers 2.2.1. Interface dipoles 2.2.2. Energy level bending 2.2.3. Injection from metal into semiconductor, and extraction 2.2.4. Excitons at interfaces 2.3. Charge transport and recombination in organic semiconductors 2.3.1. Drift transport 2.3.2. Charge carrier mobility 2.3.3. Thermally activated transport 2.3.4. Diffusion transport 2.3.5. Drift-diffusion transport 2.3.6. Space-charge limited current 2.3.7. Recombination 2.4. Mobility measurement 2.4.1. SCLC and TCLC 2.4.2. Time of flight 2.4.3. Organic field effect transistors 2.4.4. CELIV 2.5. Organic solar cells 2.5.1. Exciton diffusion towards the interface 2.5.2. Dissociation of CT states 2.5.3. CT recombination 2.5.4. Flat and bulk heterojunction 2.5.5. Transport layers 2.5.6. Thin film optics 2.5.7. Current-voltage characteristics and equivalent circuit 2.5.8. Solar cell efficiency 2.5.9. Limits of efficiency 2.5.10. Correct solar cell characterization 2.5.11. The \"O-Factor\" 3. Materials and experimental methods 3.1. Materials 3.2. Device fabrication and layout 3.2.1. Layer deposition 3.2.2. Encapsulation 3.2.3. Homogeneity of layer thickness on a wafer 3.2.4. Device layout 3.3. Characterization 3.3.1. Electrical characterization 3.3.2. Sample illumination 3.3.3. Temperature dependent characterization 3.3.4. UPS 4. Simulations 5.1. Design of single carrier devices 5.1.1. General design requirements 5.1.2. Single carrier devices for space-charge limited current 5.1.3. Ohmic regime 5.1.4. Design of injection and extraction layers 5.2. Advanced evaluation of SCLC – potential mapping 5.2.1. Potential mapping by thickness variation 5.2.2. Further evaluation of the transport profile 5.2.3. Injection into and extraction from single carrier devices 5.2.4. Majority carrier approximation 5.3. Proof of principle: POEM on simulated data 5.3.1. Constant mobility 5.3.2. Field dependent mobility 5.3.3. Field and charge density activated mobility 5.3.4. Conclusion 5.4. Application: Transport characterization in organic semiconductors 5.4.1. Hole transport in ZnPc:C60 5.4.2. Hole transport in ZnPc:C60 – temperature variation 5.4.3. Hole transport in ZnPc:C60 – blend ratio variation 5.4.4. Hole transport in ZnPc:C70 5.4.5. Hole transport in neat ZnPc 5.4.6. Hole transport in F4-ZnPc:C60 5.4.7. Hole transport in DCV-5T-Me33:C60 5.4.8. Electron transport in ZnPc:C60 5.4.9. Electron transport in neat Bis-HFl-NTCDI 5.5. Summary and discussion of the results 5.5.1. Phthalocyanine:C60 blends 5.5.2. DCV-5T-Me33:C60 5.5.3. Conclusion 6. Organic solar cell characteristics: the influence of temperature 6.1. ZnPc:C60 solar cells 6.1.1. Temperature variation 6.1.2. Illumination intensity variation 6.2. Voc in flat and bulk heterojunction organic solar cells 6.2.1. Qualitative difference in Voc(I, T) 6.2.2. Interpretation of Voc(I, T) 6.3. BHJ stoichiometry variation 6.3.1. Voc upon variation of stoichiometry and contact layer 6.3.2. V0 upon stoichiometry variation 6.3.3. Low donor content stoichiometry 6.3.4. Conclusion from stoichiometry variation 6.4. Transport material variation 6.4.1. HTM variation 6.4.2. ETM variation 6.5. Donor:acceptor material variation 6.5.1. Donor variation 6.5.2. Acceptor variation 6.6. Conclusion 7. Summary and outlook 7.1. Summary 7.2. Outlook A. Appendix A.1. Energy pay-back of this thesis A.2. Tables and registers / Organische Halbleiter sind eine neue Schlüsseltechnologie für großflächige und flexible Dünnschichtelektronik. Sie werden als dünne Materialschichten (Sub-Nanometer bis Mikrometer) auf großflächige Substrate aufgebracht. Die technologisch am weitesten fortgeschrittenen Anwendungen sind organische Leuchtdioden (OLEDs) und organische Photovoltaik (OPV). Zur weiteren Steigerung von Leistungsfähigkeit und Effizienz ist die genaue Modellierung elektronischer Prozesse in den Bauteilen von grundlegender Bedeutung. Für die erfolgreiche Optimierung von Bauteilen ist eine zuverlässige Charakterisierung und Validierung der elektronischen Materialeigenschaften gleichermaßen erforderlich. Außerdem eröffnet das Verständnis der Zusammenhänge zwischen Materialstruktur und -eigenschaften einen Weg für innovative Material- und Bauteilentwicklung. Im Rahmen dieser Dissertation werden zwei Methoden für die Materialcharakterisierung entwickelt, verfeinert und angewandt: eine neuartige Methode zur Messung der Ladungsträgerbeweglichkeit μ und eine Möglichkeit zur Bestimmung der Ionisierungsenergie IE oder der Elektronenaffinität EA eines organischen Halbleiters. Für die Beweglichkeitsmessungen wird eine neue Auswertungsmethode für raumladungsbegrenzte Ströme (SCLC) in unipolaren Bauteilen entwickelt. Sie basiert auf einer Schichtdickenvariation des zu charakterisierenden Materials. In einem Ansatz zur räumlichen Abbildung des elektrischen Potentials (\"potential mapping\", POEM) wird gezeigt, dass das elektrische Potential als Funktion der Schichtdicke V(d) bei einer gegebenen Stromdichte dem räumlichen Verlauf des elektrischen Potentials V(x) im dicksten Bauteil entspricht. Daraus kann die Beweglichkeit als Funktion des elektrischen Felds F und der Ladungsträgerdichte n berechnet werden. Die Auswertung ist modellfrei, d.h. ein Modell zum Angleichen der Messdaten ist für die Berechnung von μ(F, n) nicht erforderlich. Die Messung ist außerdem unabhängig von einer möglichen Injektionsbarriere oder einer Potentialstufe an nicht-idealen Kontakten. Die gemessene Funktion μ(F, n) beschreibt die effektive durchschnittliche Beweglichkeit aller freien und in Fallenzuständen gefangenen Ladungsträger. Dieser Zugang beschreibt den Ladungstransport in energetisch ungeordneten Materialien realistisch, wo eine klare Unterscheidung zwischen freien und Fallenzuständen nicht möglich oder willkürlich ist. Die Messung von IE und EA wird mithilfe temperaturabhängiger Messungen an Solarzellen durchgeführt. In geeigneten Bauteilen mit einem Mischschicht-Heteroübergang (\"bulk heterojunction\" BHJ) ist die Leerlaufspannung Voc im gesamten Messbereich oberhalb 180K eine linear fallende Funktion der Temperatur T. Es kann bestätigt werden, dass die Extrapolation zum Temperaturnullpunkt V0 = Voc(T → 0K) mit der effektiven Energielücke Egeff , d.h. der Differenz zwischen EA des Akzeptor-Materials und IE des Donator-Materials, übereinstimmt. Die systematische schrittweise Variation einzelner Bestandteile der Solarzellen und die Überprüfung des Einflusses auf V0 bestätigen die Beziehung V0 = Egeff. Damit kann die IE oder EA eines Materials bestimmt werden, indem man es in einem BHJ mit einem Material kombiniert, dessen komplementärer Wert bekannt ist. Messungen per Ultraviolett-Photoelektronenspektroskopie (UPS) und inverser Photoelektronenspektroskopie (IPES) werden damit bestätigt, präzisiert und ergänzt. Die beiden entwickelten Messmethoden werden auf organische Halbleiter aus kleinen Molekülen einschließlich Mischschichten angewandt. In Mischschichten aus Zink-Phthalocyanin (ZnPc) und C60 wird eine Löcherbeweglichkeit gemessen, die sowohl thermisch als auch feld- und ladungsträgerdichteaktiviert ist. Wenn das Mischverhältnis variiert wird, steigt die Löcherbeweglichkeit mit zunehmendem ZnPc-Anteil, während die effektive Energielücke unverändert bleibt. Verschiedene weitere Materialien und Materialmischungen werden hinsichtlich Löcher- und Elektronenbeweglichkeit sowie ihrer Energielücke charakterisiert, einschließlich bisher wenig untersuchter hochverdünnter Donator-Systeme. In allen Materialien wird eine deutliche Feldaktivierung der Beweglichkeit beobachtet. Die Ergebnisse ermöglichen eine verbesserte Beschreibung der detaillierten Funktionsweise organischer Solarzellen und unterstützen die künftige Entwicklung hocheffizienter und optimierter Bauteile.:1. Introduction 2. Organic semiconductors and devices 2.1. Organic semiconductors 2.1.1. Conjugated π system 2.1.2. Small molecules and polymers 2.1.3. Disorder in amorphous materials 2.1.4. Polarons 2.1.5. Polaron hopping 2.1.6. Fermi-Dirac distribution and Fermi level 2.1.7. Quasi-Fermi levels 2.1.8. Trap states 2.1.9. Doping 2.1.10. Excitons 2.2. Interfaces and blend layers 2.2.1. Interface dipoles 2.2.2. Energy level bending 2.2.3. Injection from metal into semiconductor, and extraction 2.2.4. Excitons at interfaces 2.3. Charge transport and recombination in organic semiconductors 2.3.1. Drift transport 2.3.2. Charge carrier mobility 2.3.3. Thermally activated transport 2.3.4. Diffusion transport 2.3.5. Drift-diffusion transport 2.3.6. Space-charge limited current 2.3.7. Recombination 2.4. Mobility measurement 2.4.1. SCLC and TCLC 2.4.2. Time of flight 2.4.3. Organic field effect transistors 2.4.4. CELIV 2.5. Organic solar cells 2.5.1. Exciton diffusion towards the interface 2.5.2. Dissociation of CT states 2.5.3. CT recombination 2.5.4. Flat and bulk heterojunction 2.5.5. Transport layers 2.5.6. Thin film optics 2.5.7. Current-voltage characteristics and equivalent circuit 2.5.8. Solar cell efficiency 2.5.9. Limits of efficiency 2.5.10. Correct solar cell characterization 2.5.11. The \"O-Factor\" 3. Materials and experimental methods 3.1. Materials 3.2. Device fabrication and layout 3.2.1. Layer deposition 3.2.2. Encapsulation 3.2.3. Homogeneity of layer thickness on a wafer 3.2.4. Device layout 3.3. Characterization 3.3.1. Electrical characterization 3.3.2. Sample illumination 3.3.3. Temperature dependent characterization 3.3.4. UPS 4. Simulations 5.1. Design of single carrier devices 5.1.1. General design requirements 5.1.2. Single carrier devices for space-charge limited current 5.1.3. Ohmic regime 5.1.4. Design of injection and extraction layers 5.2. Advanced evaluation of SCLC – potential mapping 5.2.1. Potential mapping by thickness variation 5.2.2. Further evaluation of the transport profile 5.2.3. Injection into and extraction from single carrier devices 5.2.4. Majority carrier approximation 5.3. Proof of principle: POEM on simulated data 5.3.1. Constant mobility 5.3.2. Field dependent mobility 5.3.3. Field and charge density activated mobility 5.3.4. Conclusion 5.4. Application: Transport characterization in organic semiconductors 5.4.1. Hole transport in ZnPc:C60 5.4.2. Hole transport in ZnPc:C60 – temperature variation 5.4.3. Hole transport in ZnPc:C60 – blend ratio variation 5.4.4. Hole transport in ZnPc:C70 5.4.5. Hole transport in neat ZnPc 5.4.6. Hole transport in F4-ZnPc:C60 5.4.7. Hole transport in DCV-5T-Me33:C60 5.4.8. Electron transport in ZnPc:C60 5.4.9. Electron transport in neat Bis-HFl-NTCDI 5.5. Summary and discussion of the results 5.5.1. Phthalocyanine:C60 blends 5.5.2. DCV-5T-Me33:C60 5.5.3. Conclusion 6. Organic solar cell characteristics: the influence of temperature 6.1. ZnPc:C60 solar cells 6.1.1. Temperature variation 6.1.2. Illumination intensity variation 6.2. Voc in flat and bulk heterojunction organic solar cells 6.2.1. Qualitative difference in Voc(I, T) 6.2.2. Interpretation of Voc(I, T) 6.3. BHJ stoichiometry variation 6.3.1. Voc upon variation of stoichiometry and contact layer 6.3.2. V0 upon stoichiometry variation 6.3.3. Low donor content stoichiometry 6.3.4. Conclusion from stoichiometry variation 6.4. Transport material variation 6.4.1. HTM variation 6.4.2. ETM variation 6.5. Donor:acceptor material variation 6.5.1. Donor variation 6.5.2. Acceptor variation 6.6. Conclusion 7. Summary and outlook 7.1. Summary 7.2. Outlook A. Appendix A.1. Energy pay-back of this thesis A.2. Tables and registers

info:eu-repo/classification/ddc/530

ddc:530