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In this work the synthesis, the spectroscopic and electrochemical investigation as well as some applications of a broad diversity of indolenine squaraine dyes were presented. This diversity was based on two parent squaraine dyes, one standard trans-configured compound (M1) and one in which one central oxygen atom was replaced by a dicyanomethylene moiety (M2), which increased the acceptor strength and induced a cis-configuration. The variety of synthesised dyes included functionalised squaraine monomers, donor- and acceptor-substituted monomeric model squaraines, donor- and acceptor-squaraine copolymers, pure squaraine homopolymers, a squaraine-squaraine copolymer, as well as some conjugated cyclic oligomers.
In order to be able to synthesise all these different kinds of dyes, several bromine and boronic ester derivatives were synthesised, which enabled the use of the Suzuki cross coupling reaction, to generate model dyes and copolymers. In addition, the bromine derivatives were used to carry out the Yamamoto homocoupling reaction to the respective homopolymers and macrocycles.
The absorption maximum of unsubstituted reference dye M1 was found at ~ 15500 cm–1, while that of M2 was red-shifted to ~ 14300 cm–1 due to the increased acceptor strength of the central unit. The extinction coefficients were in the order of ~ 300000 M–1 cm–1 and ~ 200000 M–1 cm–1, respectively. It was found that the implementation of functional groups (M3–M9), additional electron donors (M10–M19) or acceptors (M20–M22) at the periphery lead to bathochromic shifts of the absorption depending on the strength of either - and/or -donating properties of the substituents.
For the bis- and triarylamine substituted dyes M10–M13 and the dibrominated dyes M5 and M7 the electronic structure of the mono- and diradical (di)cations was explored using the interplay of cyclic voltammetry, spectroelectrochemistry, and DFT calculations. It was demonstrated that the monoradical cations still show a cyanine-like character and are delocalised Robin-Day class III species due to the low redox potential of the squaraine bridge between the additional amine redox centres. To the best of my knowledge, this made M13+∙, with an N-N-distance of 26 bonds between the additional redox centres to the longest bis(triarylamine) radical cation that is completely delocalised. For the diradical dications, the situation was of larger complexity. The computed most stable energetic state of the dianisylamine-substituted dyes turned out to be a broken-symmetry state with almost equal contributions of an open-shell singlet and triplet state. In addition, it was shown that the HOMO–1→HOMO transition dominated the absorption spectra of the diradical dications where the trans-/cis-configuration of the squaraines had a direct impact due to symmetry reasons.
Based on the donor–squaraine model compounds M10–M19, a series of donor–squaraine copolymers was synthesised (P7–P12) in order to further red shift and broaden the low energy absorption band. However, these effects were only of marginal extent. Both the optical and the electrochemical derived band gaps were barely lowered compared to the respective monomeric model dyes. This was assigned to an increased squaraine-squaraine distance and resulting lower exciton coupling between the squaraine chromophores due to the bridging units. In addition, according to semiempirical calculations the bridges were twisted out of the squaraine plane what reduced conjugational effects between the chromophores. To sum up, the idea to insert additional electron rich bridging units in order to create copolymers with broad and red-shifted absorption did not fully work out for the presented systems.
The addition of strong electron accepting NDI units at the periphery resulted in M21, the most unique monomeric model squaraine in this work. The common picture of a sharp low energy squaraine absorption completely altered due to the addition of the NDIs and a rather broad and solvent dependent low energy absorption was found. Spectroelectrochemical experiments and semiempirical calculations showed that this band is a superposition of the common squaraine HOMO→LUMO transition and a partial squaraine→NDI charge transfer transition. The latter was lost upon oxidation of the squaraine and the absorption spectrum of the monocation of M21 was found to be nearly a 1:1 image of a pure squaraine monocation. Both the monomeric model M21 and the respective copolymer P13 showed low electrochemically obtained band gaps of 1.05–1.20 eV, which were the lowest of all squaraines in this work. For both dyes, transient absorption measurements in the fs-time regime revealed the ultrafast formation of a CS state via an intermediate CT state within a few ps. Besides, charge recombination to the ground state also occured within a few ps. In the polymer, there was barely any further energy or charge transfer within the excited state lifetime and therefore the CS state was confined on adjacent squaraine-NDI pairs and did not further travel along the polymer strand.
The Ni-mediated Yamamoto homocoupling reaction was applied for the synthesis of the homopolymers (P1–P5). In contrast to the donor–squaraine copolymers, those polymers revealed strongly red-shifted and broad absorption in the red to NIR region in addition to a sharp fluorescence. These features could be explained to originate mainly from the exciton coupling of localised excited states and the presence of different superstructures in solution. For the polymers P1 and P2, an elongated J-type polymer chain caused the strong lowest energy absorption band whereas a zig-zag type arrangement of the single chromophores lead to transitions into both low and high energy excited states of the excitonic manifold. For the polymers P3 and P4, several polymer fractions of different size were investigated. Here, also an elongated chain with J-type character induced the lowest energy absorption band whereas a helical H-type arrangement caused transitions to higher energies of the excitonic manifold. The fractions to which these structures were formed depended on the chain length and the solvent. In thin film measurements, it was shown that the initially in solution formed superstructures were partly retained in the thin film but could be altered by annealing procedures. A control of the superstructures should enable the controlled tuning of the optical properties. Despite the strong interaction of the chromophores in the excited state, the redox potentials of the homopolymers barely differed to those of the respective reference dyes, indicating negligible electronic interaction in the ground state.
In addition squaraine-squaraine copolymer P6, consisting of alternating parent dyes M1 and M2, was synthesised. Likewise to the homopolymers, a broad and red-shifted absorption was observed. This was explained by exciton coupling theory, which was extended to also suit alternating copolymers. In toluene, an extraordinary narrow and intense lowest energy absorption band was observed. This exchange narrowing might be a result of a highly ordered J-type structure of the polymer especially in this solvent because it was not found in others. The features of the polymer may be compared to typical J-aggregates formed from monomeric cyanine molecules for example and the polymer used as model for excitonic interactions in an alternating copolymer. Transient absorption measurements revealed a strong energy dependence of the decay traces of the copolymer, most strikingly at early decay times. This was assigned to the occurrence of multiple excitations of one polymer strand (due to the large extinction coefficients of the polymer) and resulting exciton-exciton annihilation. Due to the large exciton diffusion constants that were estimated, the static exciton-exciton annihilation was the rate limiting process of the decay, in contrast to other conjugated polymers, where in thin film measurements the decay was diffusion controlled.
To sum up, for the polymers consisting of exclusively squaraine chromophores, it was shown that the exciton coupling of single chromophores with strong transition dipole moments was a fruitful way to tune the absorption spectra.
As a side product of some of the polycondensation reactions, unprecedented cyclic conjugated oligomers such as the triarylamine-bridged dimer Dim1, the cyclic homotrimers Tri1–Tri3, and the tetramer Tet1 were obtained by recycling GPC in low yields. Especially the cyclic trimers showed unusual absorption and even more extraordinary fluorescence properties. They showed multiple fluorescence bands in the NIR that covered a range from ~ 8000–12500 cm–1 (800–1250 nm). First hints from theoretical calculations indicated that the trimer was not fully planar but comprised a mixture of both planar and bent single squaraine chromophores. However, final results of the calculations were still missing at the time of writing.
In the last part of this work, the application of some monomeric and polymeric squaraines in binary and ternary bulk heterojunction solar cells was demonstrated. Also the utilisation as a dopant in a polymer matrix in an OLED device was shown. The homopolymers P1–P4 were tested in the binary BHJ solar cells revealing poor performances and especially very low short circuit currents. The utilisation of the polymers P3 and P4 that carried the dicyanomethylene group resulted in higher open circuit voltages due to the lower LUMO energy levels but still an overall poor performance. Neither for the different alkyl chains nor for the size of the polymers was a trend observed. In the ternary BHJ solar cells, small amounts of either monomer M14 or polymers P1A, P4–1 or P13 were added to a P3HT/PCBM system in order to generate an additional pathway for charge or energy transfer that should result in a better device performance. However, for none of the tested squaraines, improved solar cells could be built. In similarity to the binary solar cells, the short circuit currents were lower compared to a P3HT/PCBM reference device. These low short circuit currents indicated that the morphology of the squaraine dyes was the major limitation in those devices. It is possible that the dimethyl groups at the indolenine hindered a favoured alignment of the compounds that would allow decent charge transport. In the squaraine doped OLED the squaraine M6 worked rather well as an NIR emitter. Already at low dye loads the fluorescence of the host polymer SY-PPV was completely quenchend and emission from the squaraine was observed. For electroluminescence measurements, a lower dye load (0.5 wt.%) compared to the photoluminescence measurements was sufficient, indicating that apart from FRET additional quenching mechanisms were at work in the electrically driven devices such as charge carrier dynamics.
The present work aims towards the investigation of polymer degradation under biologically relevant conditions. In order to assess a potential degradation of polymers of interest for biomedical applications in vivo and associated effects on living tissue, representatives of poly(2-oxazoline)s and polypeptoids as well as poly(ethylene glycol) and poly(N-vinylpyrrolidone) for reference purposes are examined regarding their stability under oxidative and hydrolytic conditions as well as towards enzymatic degradation.
The polymers investigated in the framework of this thesis are generally considered to be non-biodegradable. Both poly(ethylene glycol) and poly(N-vinylpyrrolidone) are or were applied intensively in vivo provoking seriously harmful side effects like fatal blood poisoning from the oxidation of poly(ethylene glycol) chain ends or poly(N-vinylpyrrolidone) storage disease. Poly(2-alkyl-2-oxazoline)s and polypeptoids, both promising polymeric biomaterials for a wide variety of in vivo applications, are not clinically applied yet but undergo thorough investigations. However, comprising amide bonds within the backbone or the appending side chain, poly(2-alkyl-2-oxazoline)s and polypeptoids potentially offer a higher susceptibility towards (bio-)degradation. Representing the three most impactful initiators of degradation in vivo, the present study is focused on polymer deterioration by oxidative species, hydrolytic conditions and enzymes.
Oxidative species are generated in a variety of processes in vivo, both on purpose and as an unintentional by-product. Previous investigations revealed the susceptibility of poly(ethylene glycol), poly(N-vinylpyrrolidone), poly(2-alkyl-2-oxazoline)s and polypeptoids to deterioration by hydroxyl radicals deriving from hydrogen peroxide and copper ions. The obtained data confirm previous results of an apparent degradation rate increasing with increasing chain length due to self-inhibitory end group effects for all investigated polymer species. Although the exact concentrations of oxidative species in vivo are very controversial, with respect to their great variety and wide distribution the investigated polymers are likely prone to oxidative deterioration to some extent, with rates, mechanisms and degradation products strongly depending on the respective reactive species, polymer structure and chain length.
Like blood, most tissues of the human body benefit from a slightly alkaline pH value. Nevertheless, specific areas like the human stomach or tumor tissues possess acidic conditions potentially capable to cleave amide bonds comprised by poly(2-alkyl-2-oxazoline)s and polypeptoids. Unlike the hydrolysis of poly(2-alkyl-2-oxazoline)s resulting in side chain cleavage, the hydrolysis of polypeptoids induces backbone scission decreasing the polymer chain length tremendously and releasing, if performed exhaustively, the respective amino acids. Hydrolysis of polysarcosine is monitored by quantification of the released sarcosine via 1H-NMR spectroscopy and determination of the residual Mw via GPC. Its cyclic dimer sarcosine anhydride is formed as an intermediate product in this process via cyclization of unstable linear dimers of sarcosine.
Modification and degradation of bio(macro)molecules is an essential part of human metabolism. Polymers bearing amide bonds and showing a great similarity to natural occurring and widely distributed polypeptides, like poly(2-alkyl-2-oxazoline)s and polypeptoids, bear the potential of an enzymatic biodegradability by (more or less specific) peptidases. Just like the acidic hydrolysis described previously, peptidase activity would result in the cleavage of polymer amide bonds. The aim of the present thesis was to evaluate the stability of poly(2-alkyl-2-oxazoline)s and polypeptoids as well as poly(ethylene glycol) for the sake of reference under circumstances resembling in vivo conditions as closely as possible. Initial experiments focused on the degradation of dye-labeled upon incubation with homogenates of freshly harvested rat liver and kidney. However, although the obtained results are promising for the most part, they are considered rather unreliable and non-reproducible for various reasons. More conclusive data are attained from the incubation of non-labeled polymers in freshly laid chicken eggs. While no evidence for an enzymatic digestion of poly(ethylene glycol) in chicken egg white is found and deterioration of poly(2-methyl-2-oxazoline) upon incubation apparently derives from non-enzymatic hydrolysis, incubated polysarcosine samples reveal distinct elugram patterns depending on the respective C- and N-terminal end groups indicating both exopeptidase and endopeptidase activity. It has to be kept in mind though, that an enzymatic digestibility of polysarcosine does not necessarily imply the digestion of polypeptoids bearing longer side chains by peptidases as well, which should be investigated in further studies.
The subject of this thesis is the synthesis and characterization of PBI-based fluorescent metallosupramolecular polymers and cyclic arrays. Terpyridine receptor functionalized PBIs of predesigned geometry have been used as building blocks to construct desired macromolecular structures through metal-ion-directed self-assembly. These metallosupramolecular architectures have been investigated by NMR, UV/Vis and fluorescence spectroscopy, mass spectrometry, and atomic force microscopy.
A series of monomeric chirally substituted indolenine squaraine monomers were successfully synthesized and utilized for the construction of various oligo- and polymers, in order to study their chiroptical properties in terms of exciton chirality. The quaternary carbon atom at the 3-position of the indolenine subunit, as well as the alkyl side chain attached to the indolenine nitrogen were selected as the most suitable site for chiral functionalization.
For the C(3)-chiral derivatives, two synthetic routes depending on the desired substitution at the stereogenic center were established. The chiral side chains were prepared via Evans asymmetric alkylation where the resulting branching point at the 2 position constituted the chiral center. While the chiral substitution only had minor effects on the linear optical properties and geometric structure of the chromophore, all compounds exhibited a distinct and measurable CD signal that correlated with the distance of the chiral center to the central chromophore.
Polymers bearing chiral side chains exhibited a solvent- and temperature-dependent helix-coil equilibrium, which was influenced by the type of side chain used. CD spectroscopy revealed the helical conformation to possess a preferred twist sense, and temperature-dependent measurements showed the degree of homohelicity to be nearly complete in certain cases. Furthermore, a CPL signal was able to be obtained for the helical conformer of one polymer.
Various (co)oligo- and polymers comprising the C(3)-chiral monomers only displayed a solvent-independent J-type absorption behavior and thus did not form helical conformations in solution. CD spectroscopy revealed a solvent-dependent adoption of quasi-enantiomeric conformers, which was elucidated by quantum chemical TDDFT calculations.
In this work, the trap states in the conjugated polymer P3HT, often used as electron donor in organic bulk heterojunction solar cells, three commonly used fullerene based electron acceptors and P3HT:PC61BM blends were investigated. Furthermore, the trap states in the blend were compared with these of the pure materials. Concerning the lifetime of organic solar cells the influence of oxygen on P3HT and P3HT:PC61BM blends was studied. The experimental techniques used to investigate the trap states in the organic semiconductors were (fractional) thermally stimulated current (TSC) and current based deep level transient spectroscopy (Q-DLTS). Fractional TSC measurements on P3HT diodes revealed a quasi-continuous trap distribution. The distribution suggested two different traps in P3HT with approximately Gaussian energy distributions and maxima at about 50 meV and 105 meV. Thereby, the former was attributed to the tail states within the regular Gaussian density of states due to the low activation energy. The latter, deeper traps, however, exhibited a strong dependence on oxygen. Exposure of the P3HT diodes to oxygen, ambient air and synthetic (dry) air all revealed an increase of the deeper traps density with exposure time in the same manner. While the lower limit of the trap density in non aged P3HT samples was in the range of (1.0 − 1.2)×10^22 m^−3, it was more than doubled after an exposure of 50 h to air. An increase of the trap density with oxygen exposure time was also seen in the Q-DLTS measurements accompanied with an increase of the temperature dependence of the emission rates, indicating an enhanced formation of deeper traps. Due to the raise in density of the deeper traps, the charge carrier mobility in P3HT significantly decreased, as revealed by photo-CELIV measurements, resulting in a loss in mobility of about two orders of magnitude after 100 h exposure to synthetic air. The increased trap density was attributed to p-doping of P3HT by the transfer of an electron to adsorbed oxygen. This effect was partially reversible by applying vacuum to the sample for several hours or, more significantly, by a thermal treatment of the devices in nitrogen atmosphere. The trap states in the methanofullerenes PC61BM, bisPC61BM and PC71BM were investigated by TSC measurements. PC61BM yielded a broad quasi-continuous trap distribution with the maximum of the distribution at about 75 meV. The comparison of the TSC spectra of the three methanofullerenes exhibited significant differences in the trap states with higher activation energies of the most prominent traps in bisPC61BM and PC71BM compared to PC61BM. This probably originates from the different isomers bisPC61BM and PC71BM consist of. Each of the isomers yields different LUMO energies, where the lower ones can act as traps. The lower limit of the trap density of all of the three investigated fullerene derivatives exhibited values in the order of 10^22 m^−3, with the highest for bisPC61BM and the lowest for PC61BM. By applying fractional TSC measurements on P3HT:PC61BM solar cells, it was shown that the trap distribution in the blend is a superposition of the traps in pure P3HT and PC61BM and additional deeper traps in the range of about 250 meV to 400 meV. The origin of these additional traps, which can not be related to the pure materials, was attributed to a higher disorder in the blend and P3HT/PC61BM interfaces. This conclusion was supported by standard TSC and Q-DLTS measurements performed on pristine and annealed P3HT:PC61BM blends, exhibiting a higher ratio of the deep traps in the pristine samples. The lower limit of the trap density of the investigated annealed solar cells was in the range of (6−8)×10^22 m^−3, which was considerably higher than in the pure materials. The influence of oxygen on P3HT:PC61BM solar cells was investigated by exposure of the devices to synthetic air under specific conditions. Exposure of the solar cells to oxygen in the dark resulted in a strong decrease in the power conversion efficiency of 60 % within 120 h, which was only caused by a loss in short-circuit current. Simultaneous illumination of the solar cells during oxygen exposure strongly accelerated the degradation, resulting in an efficiency loss of 30 % within only 3 h. Thereby, short-circuit current, open-circuit voltage and fill factor all decreased in the same manner. TSC measurements revealed an increase of the density of deeper traps for both degradation conditions, which resulted in a decrease of the mobility, as investigated by CELIV measurements. However, these effects were less pronounced than in pure P3HT. Furthermore, an increase of the equilibrium charge carrier density with degradation time was observed, which was attributed to oxygen doping of P3HT. With the aid of macroscopic simulations, it was shown that the doping of the solar cells is the origin of the loss in short-circuit current for both degradation conditions.
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.
The aim of this thesis was the preparation of a biomaterial ink for the fabrication of chemically crosslinked hydrogel scaffolds with low micron sized features using melt electrowriting (MEW). By developing a functional polymeric material based on 2-alkyl-2-oxazine (Ozi) and 2-alkyl-2-oxazoline (Ox) homo- and copolymers in combination with Diels-Alder (DA)-based dynamic covalent chemistry, it was possible to achieve this goal. This marks an important step for the additive manufacturing technique melt electrowriting (MEW), as soft and hydrophilic structures become available for the first time. The use of dynamic covalent chemistry is a very elegant and efficient method for consolidating covalent crosslinking with melt processing. It was shown that the high chemical versatility of the Ox and Ozi chemistry offers great potential to control the processing parameters. The established platform offers straight forward potential for modification with biological cues and fluorescent markers. This is essential for advanced biological applications. The physical properties of the material are readily controlled and the potential for 4D-printing was highlighted as well. The developed hydrogel architectures are excellent candidates for 3D cell culture applications. In particular, the low internal strength of some of the scaffolds in combination with the tendency of such constructs to collapse into thin strings could be interesting for the cultivation of muscle or nerve cells. In this context it was also possible to show that MEW printed hydrogel scaffolds can withstand the aspiration and ejection through a cannula. This allows the application as scaffolds for the minimally invasive delivery of implants or functional tissue equivalent structures to various locations in the human body.
Several transition metal ions, like Fe2+, Co2+, Ni2+, and Zn2+ complex to the ditopic ligand 1,4-bis(2,2’:6’,2’’-terpyridin-4’-yl)benzene. Due to the high association constant, metal ion induced self-assembly of Fe2+, Co2+, and Ni2+ leads to extended, rigid-rod like metallo-supramolecular coordination polyelectrolytes (MEPEs) even in aqueous solution. Here, the kinetics of coordination and the kinetics of growth of MEPEs are presented. The species in solutions are analyzed by stopped-flow fluorescence spectroscopy, light scattering, viscometry and cryogenic transmission electron microscopy. At near-stoichiometric amounts of the reactants, high molar masses are obtained, which follow the order Ni-MEPE ~ Co-MEPE < Fe-MEPE. Furthermore, a way is presented to adjust the average molar mass, chain-length and viscosity of MEPEs using the monotopic chain stopper 4’-(phenyl)-2,2’:6’,2’’-terpyridine.
The present work builds on a conjugated electrochromic polymer with a highly transmissive and colorless bright state and its application in electrochromic devices. The main body of this work focuses on the investigation of the influence of moisture on electrochromic devices and solutions to overcome possible degradation of these devices due to moisture ingress.
Firstly, a series of EDOT derivatives with a terminal double bond in the lateral sidechain to potentially achieve a highly transmissive and fully colorless bright state was investigated. All of the EDOT derivatives were electrochemically polymerized and characterized by means of (in-situ) spectroelectrochemistry. The results highlight the dramatic influence of the terminal double bond on the improved visible light transmittance and color neutrality in the bright state. After detailed evaluation and comparison, the best performing compound, which contains a hexenyl sidechain (PEDOT-EthC6), was scaled-up by changing the deposition technique from an electrochemical to a chemical in-situ polymerization process on a R2R-pilot line in an industrially relevant environment. The R2R-processed PEDOTEthC6 half-cells were characterized in detail and provide enhanced electrochromic properties in terms of visible light transmittance and color neutrality in the bright state as well as short response times, improved contrast ratio, coloration efficiency and cycling stability (10 000 cycles).[21]
In a second step, the novel PEDOT-EthC6 electrochromic polymer was combined with a Prussian Blue counter electrode and a solid polymer electrolyte to form an all-solid-sate ECDs based on complementary switching electrodes and PET-ITO as flexible substrates. The fabricated ECDs were optically and spectroelectrochemically characterized. Excellent functionality of the S2S-processed flexible ECDs was maintained throughout 10 000 switching cycles under laboratory conditions. The ECDs offer enhanced electrochromic properties in terms of visible light transmittance change and color neutrality in the bright state as well as contrast ratio, coloration efficiency, cycling stability and fast response times. Furthermore, the final device assembly was transferred from a S2S-process to a continuous R2R-lamination process.[238]
In a third step, the PEDOT-EthC6/PB-based ECDs were submitted to conscious environmental aging tests. The emphasis of the research presented in this work, was mainly put at the influence of moisture and possible failure mechanisms regarding the PEDOT-EthC6/PB based ECDs. An intense brown coloration of the electrodes was observed while cycling the ECDs in humid atmospheres (90% rH) as a major degradation phenomenon. The brown coloration and a thereby accompanied loss of conductivity of the PET-ITO substrates was related to significant degradation of the ITO layers, inserted as the conductive layers in the flexible ECDs. A dissolution of the ITO thin films and formation of metallic indium particles on the surface of the ITO layers was observed that harmed the cycling stability enormously. The conductive layers of the aged ECDs were investigated by XRD, UV-Vis, SEM and spectroelectrochemical measurements and validated the supposed irreversible reduction of the ITO layers.[279]
In the absence of reasonable alternatives to PET-ITO for flexible (R2R-processed) ECDs, it is also important to investigate measures to avoid the degradation of ECDs. This is primarily associated with the avoidance of appropriate electrode potentials necessary for ITO reduction in humid atmospheres. As an intrinsic action point, the electrode potentials were investigated via electrochemical measurements in a three-electrode setup of an all-solid-state ECD. Extensive knowledge on the electrode potentials allowed the voltage-induced degradation of the ITO in flexible ECDs to be avoided through the implementation of an unbalanced electrode configuration (charge density ratio of working and counter electrode). It was possible to narrow the overall operational voltage window to an extent in which irreversible ITO reduction no longer occurs. The unbalanced electrode configuration lead to an improved cycling stability without harming other characteristics such as response time and light transmittance change and allows ECD operation in the presence of humidity.[279]
The avoidance of the mentioned degradation phenomena is further associated with appropriate sealing methods and materials as well as appropriate electrode and device fabrication processes. Since a variety of sealing materials is commercially available, due to the commercial launch of organic photovoltaic (OPV) and light emitting diodes (OLEDs), the focus in the present work was put to water-free electrode fabrication. As an extrinsic action point, a novel preparation method of a nanoscale PEDOT-EthC6 dispersion based on organic solvents is presented here in a final step. The water-free processing method gives access to straightforward printing and coating processes on flexible PET-ITO substrates and thus represents a promising and simplified alternative to the established PEDOT:PSS. The resulting nano-PEDOT-EthC6 thin films exhibit enhanced color neutrality and transmissivity in the bright state and are comparable to the properties of the in-situ polymerized PEDOT-EthC6 thin films.[280]