Calcium vapour deposition on semiconducting polymers studied by adsorption calorimetry and visible light absorption

Hon, Sherman Siu-Man

11 1900

A novel UHV microcalorimeter has been used to study the interaction between calcium and three polymers: MEH-PPV, MEH-PPP and P3HT. All three polymers behave differently in their reaction kinetics with calcium. On MEH-PPV we measure 45 μJ/cm² of heat generated in excess of the heat of bulk metal growth, 120 μJ/cm² for MEH-PPP, and 100 μJ/cm² for P3HT. Comparison of the MEH-PPV and MEHPPP data indicate that the initial reaction of calcium with MEH-PPV occurs at the vinylene group. We propose, based on hypothetical models, that calcium reacts with the vinylene groups of MEH-PPV with a reaction heat of 360 kJ/mol and at a projected surface density of 1.7 sites/nm², while it reacts with the phenylene groups of MEH-PPP in a two-step process with reaction heats of 200 and 360 kJ/mol respectively, at a projected surface density of 3.5 sites/nm². Optical absorption experiments, using either a 1.85 eV diode laser or a xenon lamp coupled to a scanning monochromator, have also been performed using the same calorimeter sensor. In the case of MEH-PPV, using the laser we find an optical absorption cross-section of 3E-¹⁷ cm² per incident calcium atom at low coverages. The change in absorptance at higher coverages correlates perfectly with the population of reacted Ca atoms determined calorimetrically. The size of the absorbance cross-section, and its position just within the band gap of the polymer, are consistent with the reaction being one of polaron formation. Calcium does not appear to dope P3HT, while the photon energy range of 1.5 to 3.75 eV used in these experiments is likely too small for probing polaronic energy states in MEH-PPP. / Science, Faculty of / Chemistry, Department of / Graduate

Calorimetry

Physical chemistry

Surface science

Semiconducting polymers

Polymer metallization

MEH-PPV

MEH-PPP

P3HT

A Bottom-up Computational Approach to Semiconducting Block Copolymers

Raychev, Deyan

11 July 2019

Conjugated polymers are very attractive materials for the scientists and industry due to low cost of the organic compounds, their lightweight, easy large-area processing from solution at low temperature and mechanical flexibility. Moreover, these materials are multifunctional and advanced technologies require both simultaneous n- and p-type conductance, i.e. ambipolarity. However, there are some hindrances which do not allow the wide spreading of this new generation of semiconductors into the market, first of all, due to their instability to ambient conditions. Moreover, determination of the tunable parameters which are responsible for high efficiency and controlled crystal packing ordering of the devices is rather complicated. A lot of efforts are done in order to improve the performance of the organic electronics as well as to shed light on the relation between the chemical structure and their intrinsic properties. Additionally, the governing factors which define the conductive properties of these materials are still under debate and this remains a great challenge for the researchers. One way to gain insight into the characteristics of polymeric materials is to begin exploring the polymers from their small constitutive units and then step-by-step to construct and characterize every compound up to macromolecular level. In this work, the semiconducting block copolymers, as promising candidates for application in organic transistors, are investigated starting from their small donor and acceptor blocks up to monomers and macromolecules, using computational methods running on different time and length scales. It is found out that the charge transport depends on the symmetry of molecules and the hopping mobilities can be predicted from isolated stacks of dimers, which are defined by minimum energy, without knowledge of the actual crystal structure. Interestingly, the polymers moieties prefer to build up mixed stacks and the flanks form segregated columns if there are no present defects in the samples. At each step of the investigation the results are compared with available experimental data.

info:eu-repo/classification/ddc/540

ddc:540

Systematic Synthesis of Organic Semiconductors with Variable Band Gaps

Scilla, Christopher Thomas

01 May 2012

Polymeric materials are attractive candidates for the fabrication of low cost, large area photovoltaic devices. Controlling the band gap of the electroactive polymer is an essential factor in optimizing the resulting devices. In this dissertation, a methodology for the synthesis of well-defined semiconducting materials with tunable band gaps is described. First, the synthesis, characterization, and computational analysis of a variety of trimers consisting of two 3-hexylthiophene units flanking a central moiety consisting of thiophene, or one of the electron donating monomers isothianaphthene or thieno[3,4,b]thiophene will be described. From this analysis the influences of the electronic and steric structure of the materials will be investigated. Several of these trimers will then be used in the synthesis of well-defined, higher order, oligomers of thiophene and isothianaphthene in varying compositions. Polymerization of these oligomers yields polymers of known sequence allowing the band gap of the polymers to be systematically varied. Finally, preliminary investigations into the development of alternate oligomer core units will be described. The control over the band gap that this method affords will be useful in the optimization of polymeric semiconductor devices.

Band Gap

Isothianaphthene

Organic Photovoltaics

Polythiophene

Semiconducting Polymers

Thieno[3

4

b]thiophene

Engineering

Polymer Science

Nanoparticle-based Organic Energy Storage with Harvesting Systems

Al Haik, Mohammad Yousef

04 May 2016

A new form of organic energy storage devices (organic capacitors) is presented in the first part of this dissertation. The storage devices are made out of an organic semiconductor material and charge storage elements from synthesized nanoparticles. The semiconducting polymer is obtained by blending poly (vinyl alcohol) and poly (acrylic acid) in crystal state polymers with a known plasticizer; glycerol or sorbitol. Synthesized nanoparticles namely, zinc-oxide (ZnO), erbium (Er), cadmium sulfide (CdS), palladium (Pd) and silver-platinum (AgPt) were used as charge storage elements in fabrication of metal-insulator-semiconductor (MIS) structure. The organic semiconductor and synthesized nanoparticles are tested to evaluate and characterize their electrical performance and properties. Fabrication of the organic capacitors consisted of layer-by-layer deposition and thermal evaporation of the electrode terminals. Capacitance versus voltage (C-V) measurement tests were carried out to observe hysteresis loops with a window gate that would indicate the charging, discharging and storage characteristics. Experimental investigation of various integrated energy harvesting techniques combined with these organic based novel energy storage devices are performed in the second part of this dissertation. The source of the energy is the wind and is harvested by means of miniature wind turbines and vibrations, using piezoelectric transduction. In both cases, the generated electric charge is stored in these capacitors. The performance of the organic capacitors are evaluated through their comparison with commercial capacitors. The results show that the voltage produced from the two energy harvesters was high enough to store the harvested energy in the organic capacitors. The charge and energy levels of the organic capacitors are also reported. The third part of this dissertation focuses on harvesting energy from a self-induced flutter of a thin composite beam. The composite beam consisted of an MFC patch bonded near the clamped end and placed vertically in the center of a wind tunnel test section. The self sustaining energy harvesting from the unimorph composite beam is exploited. The effects of different operational parameters including the optimum angle of attack, wind speed and load resistance are determined. / Ph. D.

Energy Storage Devices

Energy harvesting

Organic Semiconducting Polymers

Nanoparticles

Composites

Fluttering

Solution Processable Conducting Films based on Doped Polymers:

Karpov, Yevhen

28 November 2017

Thesis describes recent advances in the synthesis of donor-acceptor conjugated copolymers and their efficient doping via molecular p-dopants.

Organic electronics

semiconducting polymers

donor-acceptor polymer

doping

conductivity

dopant

synthesis

morphology

calculations

reaction mechanism

ddc:540

rvk:UP 7500

Organic electronics

semiconducting polymers

donor-acceptor polymer

doping

conductivity

dopant

synthesis

morphology

calculations

reaction mechanism

Solution Processable Conducting Films based on Doped Polymers:: Synthesis and Characterization

Karpov, Yevhen

10 November 2017

Thesis describes recent advances in the synthesis of donor-acceptor conjugated copolymers and their efficient doping via molecular p-dopants.:Chapter I Preface Motivation and Goals Outline 7 Chapter II 8 State of the Art & Characterization Techniques 8 2.1. General Introduction 8 2.1.1. Concept of Conjugated Polymers 9 2.1.2. Electronic Conduction and Necessity of Doping in Conjugated Polymers 11 2.1.3. Solubility and Processing. 14 2.2. Doping 17 2.2.1. Concept of Doping in Conjugated Polymers 17 2.2.2. Morphological Changes of the Material upon Doping. Conductivity. 20 2.2.3. State-of-the-art p-dopants. 23 2.3. Synthetic Strategies for the Design of (Semi)conducting Polymers 28 2.3.1. A Concise Review: from Polyacetylene till Modern DA Polymers 28 2.3.2. Synthetic Routes to Conjugated Polymers 31 2.3.3. Step-growth vs Chain-growth 34 2.3.4. Benchmark solution-processable Polymers 38 2.4. Characterization techniques 41 2.4.1. Conductivity Measurements 41 2.4.2. Electrochemical Voltammetry 42 2.4.3. Uv-vis-near-infrared 44 2.4.4. Attenuated Total Reflectance Fourier Transform Infrared Spectroscopy. 44 2.4.5. Morphological studies. 45 2.4.6. Electron Spin Resonance Spectroscopy. 46 Chapter III 48 Results & Discussion 48 3.1. Diketopyrrolopyrrole-Based Copolymers 50 3.1.1. Motivation 50 3.1.2. Results and Discussion 51 3.1.4. Summary 89 3.2. Naphthalene Diimide-based Copolymer 90 3.2.1. Motivation 90 3.2.2. Results and Discussion 92 3.2.4. Summary 105 3.3. Isoindigo-Based Copolymers 107 3.3.1. Motivation 107 3.3.2. Results and Discussion 108 3.3.4. Summary 119 Summary & Conclusions 120 Outlook 123 Chapter IV 125 Experimental Part 125 4.1. General Methods and Instrumentation 125 4.2. Synthesis 129 4.2.1. Synthesis of diketopyrrolopyrrole copolymer. 129 4.2.2. Synthesis of electron-conducting polymer (PNDIT2) 132 4.2.3. Synthesis of polyisoIndigo 132 4.2.3. Synthesis of Dopants 135 4.3. Cyclic voltammetry measurements 136 4.4. GIWAX data. 143 4.5. Films preparation 145 References 147 Table of Abbreviations 159 List of Publications 161 Acknowledgements 162 Appendix 163

info:eu-repo/classification/ddc/540

ddc:540

Estudo da interação interfacial entre polímeros semicondutores e metais ou surfactantes / Investigation of interfacial interaction between polymers and metal or surfactants

Maia, Francisco Carlos Barbosa

01 September 2011

Esta Tese aborda duas importantes vertentes de pesquisa em polímeros conjungados (PC), bastante relevantes na Eletrônica Orgânica (EO) e na área de Biossensores. Com respeito à EO, estudam-se as interfaces PC - metal (M) por meio da espectroscopia vibracional de Geração de Soma de Frequências, cuja sigla mais comum é SFG - derivada do seu nome inglês Sum Frequency Generation. Este problema é de grande importância porque na interface acontecem fenômenos essenciais para o funcionamento de dispositivos, como por exemplo a injeção e coleta de cargas. Deve-se ressaltar que poucos trabalhos na literatura investigam o problema da interface PC-M, e aqueles que o fazem, ou sondam interfaces diferentes daquelas de dispositivos reais, ou são estudos teóricos, com necessidade da comprovação experimental, ou ainda usam ferramentas sem especificidade a interfaces. Neste ponto, o estudo da interface PC-M feita nesta Tese apresenta como expressivo diferencial o uso da espectroscopia SFG às interfaces PC-M do tipo encontrado em dispositivos usuais da EO. A técnica SFG permite determinar o ordenamento molecular nas interfaces através da análise quantitativa das vibrações das duplas ligações dos PC, que é a região molecular ativa durante o funcionamento dos dispositivos da EO. Além disso, a simples análise qualitativa dos espectros SFG indica a ocorrência de dopagem (transferência de carga) em algumas interfaces PC-M. Dentre as conclusões deste trabalho, destaca-se o entendimento de como a organização molecular da interface influencia a transferência de carga espontânea entre PC e M. Para tanto, construiu-se um modelo de ordenamento molecular (MOM) baseado nos resultados de SFG, que levando em conta o alinhamento energético (AE) entre os níveis de Fermi dos materiais na interface, estabelece a correlação entre arranjo molecular e transferência de carga. Para o estudo, escolheram-se os metais Al e Au, e os PCs comerciais poli(3-hexiltiofeno) (P3HT) regioregular e poli(9,9-dioctilfluoreno) (PF8), por serem comumente usados em dispositivos da EO. A combinação MOM-AE explica, por exemplo, a não ocorrência de dopagem nas interfaces P3HT-M. Neste caso, o MOM prevê o empacotamento π ao longo do plano da superfície metálica de modo que o contato PC-M estabelece-se através das cadeias alquila (isolantes) do P3HT. No caso de PF8-Au, verifica-se dopagem tipo p. Na interface PF8-Al, embora existam cadeias alinhadas à superfície metálica e com o plano dos anéis paralelo à mesma, favorecendo a transferência de carga, a igualdade das funções trabalho (AE) de cada material impede a dopagem. Também se verificaram diferenças quantitativas no ordenamento molecular do PC em função do método de preparação da amostra: i) PC depositado sobre substrato metálico ou ii) metal evaporado sobre filme do PC. De forma qualitativa, analisam-se copolímeros: poli(9,9-n-dihexil-2,7-fluorenodiilvinileno-alt-2,5 tiofeno) (L29) e iv) poli(9,9-di-hexilfluorenodiilvinileno-alt-1,4-fenilenovinileno) (L16), em interfaces com os mesmos metais. Neste caso, observa-se dopagem em todas as interfaces. O estudo inserido na área de Biosensores é motivado pela vasta gama de trabalhos que relatam o uso das propriedades ópticas (PO) de PEC como ferramenta sensora em sistemas biológicos, e sua modulação via interação com surfactantes. Foi então realizada a análise, por meio de técnicas de espectroscopia óptica convencional - Absorção Óptica (AO) e Fotoluminescência (PL) - e da técnica de Microcalorimetria Isotérmica por Titulação, da interação entre polieletrólitos conjugados (PEC) e surfactantes em solução aquosa. A formação do complexo PEC+surfactante ocorre mediante modificação do estado de agregação do polímero que, por sua vez, gera alterações em suas POs. Assim este estudo visa o entendimento de como as forças hidrofóbicas, eletrostáticas, fatores termodinâmicos e estrutura química de PECs e surfactantes influenciam as POs dos complexos formados. Pela primeira vez na literatura, relata-se a ocorrência de interação eletrônica entre PEC e surfactante. Isto acontece no caso do complexo formado pelo PEC aniônico, derivado do PPV, o poli [5 - metoxi 2 - (3 sulfopropoxi) - 1,4 fenilenovinileno] (MPSPPV), e o surfactante dodecilbenzeno sulfonato de sódio (DBS). A inédita interação eletrônica ocorre em solução, resultando em dramáticas modificações nos estados eletrônicos do MPSPPV devido à forte interação hidrofóbica com o DBS. Isto gera expressivos deslocamentos, em torno de 0,5 eV ou 100 nm, para a luminescência do complexo em relação à do MPSPPV puro. Isso torna o complexo MPSPPV+DBS bastante promissor, pois apresenta POs sintonizáveis, em função da concentração de surfactante. Para explicar as novas POs do complexo MPSPPV+DBS, propõe-se um modelo baseado na formação do complexo MPSPPV+DBS autoorganizado em um arranjo molecular específico. Neste arranjo, a proximidade entre os grupos conjugados de cada molécula leva ao realinhamento dos níveis energéticos, sob regime de forte acoplamento. A fim de estender e generalizar o trabalho, estudam-se surfactantes de diversas estruturas químicas ao constituírem complexos com o PEC aniônico (MPSPPV) e com o PEC catiônico, o poli [2,5 - bis ( 2 - (n, n -dietilamônio brometo) etoxi) - 1, 4 - alt - 1, 4 - fenileno] (DAB). Os surfactantes estudados são: dodecil sulfato de sódio (SDS), dodecilbenzeno sulfonato de sódio (DBS), t - octil - fenoxi - polietoxi - etanol (TX100) e dodeciltrimetil brometo de amônia (DTAB). Essas descobertas podem ter implicações importantes para o projeto de plataformas para aplicações em biosensores, e para a melhoria do desempenho e durabilidade de dispositivos de EO. / This Thesis addresses two important branches of the conjugated polymer (CP) research which are relevant to Organic Electronics (OE) and Biosensors. Concerning OE, the interfaces CP-metal (M) are studied by the Sum-Frequency Generation (SFG) vibrational spectroscopy. This problem is quite important since fundamental phenomena that are essential to the performance of organic devices take place at this interface, such as charge injection and collection. It should be stressed that few papers in the literature focus on the CP-M interface, and they either probe different interfaces from those present in the devices, or use analytical tools without specificity to the interfaces, or else they are theoretical studies requiring experimental verification. In this regard, the study of the CP-M interface accomplished in this Thesis shows the advantage over previous studies due to the use of SFG spectroscopy to the CP-M interfaces usually found in the organic devices. Furthermore, SFG spectroscopy allows a determination of the molecular arrangement at the interfaces by a quantitative analysis of the vibrations of the double bonds, which are the molecular regions directly involved in the operation of OE devices. Furthermore, a simple and qualitative analysis of the SFG spectra leads to the recognition of doping (charge transfer) in some CP-M interfaces. Among the most important conclusions, emerges the understanding of how the molecular order affects the spontaneous charge transfer between PC and M at the interface. This was attained through a molecular order model (MOM) based on the SFG results and on the energy alignment (EA) between the Fermi levels of the PC and metal at the interface. For this study were used the metals Al and Au, and the commercial CPs regioregular poly(3-hexylthiofene) (P3HT) and poly(9,9-dioctylfluorene) (PF8), which are commonly used in OE. The MMO-EA combination explains that reason for not detecting doping in P3HT-M interfaces, where the MMO has suggested π-stacking along the surface plane, resulting in little interaction between CPs electrons with the metal. The p-doping is found in the PF8-Au interface. For the interface PF8-Al, although the MMO implies that the polymeric chains are aligned to the metallic surface with their aromatic rings parallel to the surface, which is favorable for charge transfer process, the equality between the work functions (EA) of the materials prevents doping. It has also been observed quantitative differences in chain orientation for samples prepared by different methods: i) CP film spread over metallic substrates and ii) metal evaporated onto CP films. In a qualitative way, the 2 copolymers - poly(9,9-n-dihexyl-2,7-fluorenediilvinylene-alt-2,5 thiophene) (L29) and poly(9,9-di-hexylfluorenediilvinylene-alt-1,4-fenilenevinylene) (L16) - were analyzed at interfaces with the same metals. In all these cases, doping is observed. The study related to Biosensors is motivated by the large number of paper reporting the use of optical properties (OP) of CPE as a sensing tool in biological systems, and their modulation via interaction with surfactants. Therefore, an investigation of the interaction between conjugated polyelectrolytes (CPE) and surfactants in aquous solution was performed by convencional optical spectroscopy - Optical Absorbance (OA) and Photoluminescence (PL) - and the thermodynamic technique named Isothermal Titration Microcalometry. The formation of the CPE+surfactant complex is followed by modifications in the aggregation state of the polymer, which in turn generates modifications on its OPs. Therefore, this study aims the understanding of how hydrophobic and/or electrostatic forces, thermodynamic factors and chemical structure of the CPE and surfactants affect the OPs of the complexes. For the first time in the literature related to PEC+surfactant complexes, electrocnic interaction is noticed when the an anionic PPV derivative, poly [5 - metoxy 2 (3 sulfopropoxi) 1,4 fenilenovinileno] (MPSPPV), interacts with the surfactant Sodium dodecylbenzene sulfatonate (DBS). The striking electronic interaction occours in aqueous solution and dramatic modifications takes place in the electronic states of MPSPPV due to its strong hydrophobic interaction with DBS. The PL of complex MPSPPV+DBS presents a remarkable blue-shift of about 0,5 eV (or 100 nm), when compared to the PL of MPSPPV. Consequently, the MPSPPV+DBS has tunable OPs, within a wide range of the visible spectrum, as a function of the surfactant concentration. In order to explain these changes of OPs, is proposed a model based on the formation of a self-organized MPSPPV+DBS complex with a specific molecular arrangement. In this hybrid aggregate, the small distance between the conjugated groups of each molecule leads to a realignment of the energy levels. The complete study, however, investigated the complexes formed with the surfactants: Sodium dodecyl sulfate (SDS), Sodium dodecylbenzene sulfatonate (DBS), t - octyl - phenoxy - polyethoxy - ethanol (TX100) and dodecyltrimethyl Ammonium Bromide (DTAB), in interaction with both the anionic PEC (MPSPPV) and the cationic poly [2,5 - bys ( 2 - (n, n -diethylammonium bromide) ethoxy) - 1, 4 - alt - 1, 4 - fenylene] (DAB). These discoveries are expected to have important implications to the design of platforms for biosensor applications, and to the improvement of performance and durability of OE devices.

Espectroscopia vibracional

Interfaces metálicas

Metallic interfaces

Non linear optics

Óptica não linear

Polímeros semicondutores

Semiconducting polymers

Surfactantes

Surfactants

Vibrational spectroscopy

Estudo da interação interfacial entre polímeros semicondutores e metais ou surfactantes / Investigation of interfacial interaction between polymers and metal or surfactants

Francisco Carlos Barbosa Maia

01 September 2011

Esta Tese aborda duas importantes vertentes de pesquisa em polímeros conjungados (PC), bastante relevantes na Eletrônica Orgânica (EO) e na área de Biossensores. Com respeito à EO, estudam-se as interfaces PC - metal (M) por meio da espectroscopia vibracional de Geração de Soma de Frequências, cuja sigla mais comum é SFG - derivada do seu nome inglês Sum Frequency Generation. Este problema é de grande importância porque na interface acontecem fenômenos essenciais para o funcionamento de dispositivos, como por exemplo a injeção e coleta de cargas. Deve-se ressaltar que poucos trabalhos na literatura investigam o problema da interface PC-M, e aqueles que o fazem, ou sondam interfaces diferentes daquelas de dispositivos reais, ou são estudos teóricos, com necessidade da comprovação experimental, ou ainda usam ferramentas sem especificidade a interfaces. Neste ponto, o estudo da interface PC-M feita nesta Tese apresenta como expressivo diferencial o uso da espectroscopia SFG às interfaces PC-M do tipo encontrado em dispositivos usuais da EO. A técnica SFG permite determinar o ordenamento molecular nas interfaces através da análise quantitativa das vibrações das duplas ligações dos PC, que é a região molecular ativa durante o funcionamento dos dispositivos da EO. Além disso, a simples análise qualitativa dos espectros SFG indica a ocorrência de dopagem (transferência de carga) em algumas interfaces PC-M. Dentre as conclusões deste trabalho, destaca-se o entendimento de como a organização molecular da interface influencia a transferência de carga espontânea entre PC e M. Para tanto, construiu-se um modelo de ordenamento molecular (MOM) baseado nos resultados de SFG, que levando em conta o alinhamento energético (AE) entre os níveis de Fermi dos materiais na interface, estabelece a correlação entre arranjo molecular e transferência de carga. Para o estudo, escolheram-se os metais Al e Au, e os PCs comerciais poli(3-hexiltiofeno) (P3HT) regioregular e poli(9,9-dioctilfluoreno) (PF8), por serem comumente usados em dispositivos da EO. A combinação MOM-AE explica, por exemplo, a não ocorrência de dopagem nas interfaces P3HT-M. Neste caso, o MOM prevê o empacotamento π ao longo do plano da superfície metálica de modo que o contato PC-M estabelece-se através das cadeias alquila (isolantes) do P3HT. No caso de PF8-Au, verifica-se dopagem tipo p. Na interface PF8-Al, embora existam cadeias alinhadas à superfície metálica e com o plano dos anéis paralelo à mesma, favorecendo a transferência de carga, a igualdade das funções trabalho (AE) de cada material impede a dopagem. Também se verificaram diferenças quantitativas no ordenamento molecular do PC em função do método de preparação da amostra: i) PC depositado sobre substrato metálico ou ii) metal evaporado sobre filme do PC. De forma qualitativa, analisam-se copolímeros: poli(9,9-n-dihexil-2,7-fluorenodiilvinileno-alt-2,5 tiofeno) (L29) e iv) poli(9,9-di-hexilfluorenodiilvinileno-alt-1,4-fenilenovinileno) (L16), em interfaces com os mesmos metais. Neste caso, observa-se dopagem em todas as interfaces. O estudo inserido na área de Biosensores é motivado pela vasta gama de trabalhos que relatam o uso das propriedades ópticas (PO) de PEC como ferramenta sensora em sistemas biológicos, e sua modulação via interação com surfactantes. Foi então realizada a análise, por meio de técnicas de espectroscopia óptica convencional - Absorção Óptica (AO) e Fotoluminescência (PL) - e da técnica de Microcalorimetria Isotérmica por Titulação, da interação entre polieletrólitos conjugados (PEC) e surfactantes em solução aquosa. A formação do complexo PEC+surfactante ocorre mediante modificação do estado de agregação do polímero que, por sua vez, gera alterações em suas POs. Assim este estudo visa o entendimento de como as forças hidrofóbicas, eletrostáticas, fatores termodinâmicos e estrutura química de PECs e surfactantes influenciam as POs dos complexos formados. Pela primeira vez na literatura, relata-se a ocorrência de interação eletrônica entre PEC e surfactante. Isto acontece no caso do complexo formado pelo PEC aniônico, derivado do PPV, o poli [5 - metoxi 2 - (3 sulfopropoxi) - 1,4 fenilenovinileno] (MPSPPV), e o surfactante dodecilbenzeno sulfonato de sódio (DBS). A inédita interação eletrônica ocorre em solução, resultando em dramáticas modificações nos estados eletrônicos do MPSPPV devido à forte interação hidrofóbica com o DBS. Isto gera expressivos deslocamentos, em torno de 0,5 eV ou 100 nm, para a luminescência do complexo em relação à do MPSPPV puro. Isso torna o complexo MPSPPV+DBS bastante promissor, pois apresenta POs sintonizáveis, em função da concentração de surfactante. Para explicar as novas POs do complexo MPSPPV+DBS, propõe-se um modelo baseado na formação do complexo MPSPPV+DBS autoorganizado em um arranjo molecular específico. Neste arranjo, a proximidade entre os grupos conjugados de cada molécula leva ao realinhamento dos níveis energéticos, sob regime de forte acoplamento. A fim de estender e generalizar o trabalho, estudam-se surfactantes de diversas estruturas químicas ao constituírem complexos com o PEC aniônico (MPSPPV) e com o PEC catiônico, o poli [2,5 - bis ( 2 - (n, n -dietilamônio brometo) etoxi) - 1, 4 - alt - 1, 4 - fenileno] (DAB). Os surfactantes estudados são: dodecil sulfato de sódio (SDS), dodecilbenzeno sulfonato de sódio (DBS), t - octil - fenoxi - polietoxi - etanol (TX100) e dodeciltrimetil brometo de amônia (DTAB). Essas descobertas podem ter implicações importantes para o projeto de plataformas para aplicações em biosensores, e para a melhoria do desempenho e durabilidade de dispositivos de EO. / This Thesis addresses two important branches of the conjugated polymer (CP) research which are relevant to Organic Electronics (OE) and Biosensors. Concerning OE, the interfaces CP-metal (M) are studied by the Sum-Frequency Generation (SFG) vibrational spectroscopy. This problem is quite important since fundamental phenomena that are essential to the performance of organic devices take place at this interface, such as charge injection and collection. It should be stressed that few papers in the literature focus on the CP-M interface, and they either probe different interfaces from those present in the devices, or use analytical tools without specificity to the interfaces, or else they are theoretical studies requiring experimental verification. In this regard, the study of the CP-M interface accomplished in this Thesis shows the advantage over previous studies due to the use of SFG spectroscopy to the CP-M interfaces usually found in the organic devices. Furthermore, SFG spectroscopy allows a determination of the molecular arrangement at the interfaces by a quantitative analysis of the vibrations of the double bonds, which are the molecular regions directly involved in the operation of OE devices. Furthermore, a simple and qualitative analysis of the SFG spectra leads to the recognition of doping (charge transfer) in some CP-M interfaces. Among the most important conclusions, emerges the understanding of how the molecular order affects the spontaneous charge transfer between PC and M at the interface. This was attained through a molecular order model (MOM) based on the SFG results and on the energy alignment (EA) between the Fermi levels of the PC and metal at the interface. For this study were used the metals Al and Au, and the commercial CPs regioregular poly(3-hexylthiofene) (P3HT) and poly(9,9-dioctylfluorene) (PF8), which are commonly used in OE. The MMO-EA combination explains that reason for not detecting doping in P3HT-M interfaces, where the MMO has suggested π-stacking along the surface plane, resulting in little interaction between CPs electrons with the metal. The p-doping is found in the PF8-Au interface. For the interface PF8-Al, although the MMO implies that the polymeric chains are aligned to the metallic surface with their aromatic rings parallel to the surface, which is favorable for charge transfer process, the equality between the work functions (EA) of the materials prevents doping. It has also been observed quantitative differences in chain orientation for samples prepared by different methods: i) CP film spread over metallic substrates and ii) metal evaporated onto CP films. In a qualitative way, the 2 copolymers - poly(9,9-n-dihexyl-2,7-fluorenediilvinylene-alt-2,5 thiophene) (L29) and poly(9,9-di-hexylfluorenediilvinylene-alt-1,4-fenilenevinylene) (L16) - were analyzed at interfaces with the same metals. In all these cases, doping is observed. The study related to Biosensors is motivated by the large number of paper reporting the use of optical properties (OP) of CPE as a sensing tool in biological systems, and their modulation via interaction with surfactants. Therefore, an investigation of the interaction between conjugated polyelectrolytes (CPE) and surfactants in aquous solution was performed by convencional optical spectroscopy - Optical Absorbance (OA) and Photoluminescence (PL) - and the thermodynamic technique named Isothermal Titration Microcalometry. The formation of the CPE+surfactant complex is followed by modifications in the aggregation state of the polymer, which in turn generates modifications on its OPs. Therefore, this study aims the understanding of how hydrophobic and/or electrostatic forces, thermodynamic factors and chemical structure of the CPE and surfactants affect the OPs of the complexes. For the first time in the literature related to PEC+surfactant complexes, electrocnic interaction is noticed when the an anionic PPV derivative, poly [5 - metoxy 2 (3 sulfopropoxi) 1,4 fenilenovinileno] (MPSPPV), interacts with the surfactant Sodium dodecylbenzene sulfatonate (DBS). The striking electronic interaction occours in aqueous solution and dramatic modifications takes place in the electronic states of MPSPPV due to its strong hydrophobic interaction with DBS. The PL of complex MPSPPV+DBS presents a remarkable blue-shift of about 0,5 eV (or 100 nm), when compared to the PL of MPSPPV. Consequently, the MPSPPV+DBS has tunable OPs, within a wide range of the visible spectrum, as a function of the surfactant concentration. In order to explain these changes of OPs, is proposed a model based on the formation of a self-organized MPSPPV+DBS complex with a specific molecular arrangement. In this hybrid aggregate, the small distance between the conjugated groups of each molecule leads to a realignment of the energy levels. The complete study, however, investigated the complexes formed with the surfactants: Sodium dodecyl sulfate (SDS), Sodium dodecylbenzene sulfatonate (DBS), t - octyl - phenoxy - polyethoxy - ethanol (TX100) and dodecyltrimethyl Ammonium Bromide (DTAB), in interaction with both the anionic PEC (MPSPPV) and the cationic poly [2,5 - bys ( 2 - (n, n -diethylammonium bromide) ethoxy) - 1, 4 - alt - 1, 4 - fenylene] (DAB). These discoveries are expected to have important implications to the design of platforms for biosensor applications, and to the improvement of performance and durability of OE devices.

Espectroscopia vibracional

Interfaces metálicas

Óptica não linear

Polímeros semicondutores

Surfactantes

Metallic interfaces

Non linear optics

Semiconducting polymers

Surfactants

Vibrational spectroscopy

Acceptor Moieties With Extended Conjugation For Semiconducting Polymers

Xuyi Luo (12463584)

27 April 2022

<p>New acceptor moieties with extended conjugation have been developed  for further understanding of structure-property relationships in donor-acceptor type semiconducting polymers. These diketopyrrolopyrrole or isoindigo based conjugated polymers have been demonstrated as functional materials in organic field effect transistors, photoacoustic imaging and organic electrochemical transistors. With demonstrations of semiconducting molecular design, we hope to spark new research directions especially on deeper investigation of charge transport dependence on chemical structures, and new design strategies of acceptor moieties with extended conjugation could be applied for targeted applications.</p>

Functional Materials

Synthesis of Materials

semiconducting polymers

organic electrochemical transistors

Organic Field Effect TransistorsCompared

Synthesis of conjugated polymers from xanthene and alkenyl flanked diketopyrrolopyrrole monomers for high-performance electronic applications.

Wahalathantrige Don, Ranganath Wijesinghe

13 May 2022

In traditional electronics, inorganic materials such as silicon and germanium are used as semiconductors due to their outstanding semiconducting properties. Unfortunately, inorganic materials are rigid due to their high crystalline nature, and processing these materials is complex and expensive. Furthermore, traditional semiconducting materials do not have favorable mechanical properties in applications such as wearable devices and large-area applications with complicated shapes. Conjugated conducting polymers (CCPs) are being explored as alternative materials to conventional semiconductors due to their mechanical properties and high conductivity. CCPs offer properties such as solution and low-temperature processability, flexibility, thermal and optical properties that traditional semiconductors could not provide. These characteristics are essential in Organic Light-Emitting Diodes (OLEDs), Organic Field-Effect Transistors (OFETs), and Photovoltaic (PVs) devices. This dissertation focuses on synthesizing rhodamine- and diketopyrrolopyrrole- containing CCPs. Chapter I focuses on the synthesis, and characterization of polyrhodamine (PRho), a semiconducting conjugated polymer containing the rhodamine core in the polymer’s backbone. PRho was synthesized by the Buchwald-Hartwig polycondensation and characterized for its optical and electrochemical properties. We have discovered that the polymer is electrochemically reversible and stable up to 1000 cycles as recorded by cyclic voltammetry between -0.4 and 1.0 V vs. Ag/AgCl and stable to extreme acidic and basic conditions without noticeable degradation. Remarkably, the polymer has a conductivity in the semiconductor range of 8.38 x 10-2 S cm–1 when treated with 20% HCl. Chapter II focuses on the synthesis and characterization of four different alkenyl flanked diketopyrrolopyrrole (DPP) polymers ( PDPPVTV, PDPPVTT, PDPPV3T, and PDPPV4T) synthesized via Stille polycondensation. Different pi-conjugated segments (alkenyl/ PDPPVTV, thiophene/ PDPPVTT, thienothiophene/ PDPPV3T, and dithienothiophene/ PDPPV4T) were used to tune the optoelectrical properties of the polymers. The effect of the alkenyl groups and different pi-conjugated segments on the optoelectrical and charge mobility properties were determined by UV/visible spectroscopy, cyclic voltammetry, and FET characteristics. Three of the four polymers, except PPP4T, showed good solubility in chloroform. All the polymers showed high thermal stabilities in TGA and semi-crystalline nature in X-Ray diffraction patterns. PDPPVTV and PDPPVTT exhibited hole mobilities of 1.8 x 10-3 cm2 V-1 s-1 and 0.25 cm2 V-1 s-1, respectively. .

Semiconducting polymers

DPP

OFET

Conjugated polymers

Donor-Acceptor polymers

Xanthene polymers

Rhodamine polymers

DPP polymers

Organic Chemistry

Polymer Chemistry