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This project was focused on generating ultra thin stimuli responsive membranes with an embedded transmembrane protein to act as the pore. The membranes were formed by crosslinking of transmembrane protein polymer conjugates. The conjugates were self assembled on air water interface and the polymer chains crosslinked using a UV crosslinkable comonomer to engender the membrane. The protein used for the studies reported herein was one of the largest transmembrane channel proteins, ferric hydroxamate uptake protein component A (FhuA), found in the outer membrane of Escherichia coli (E. coli). The wild type protein and three genetic variants of FhuA were provided by the group of Prof. Schwaneberg in Aachen. The well known thermo responsive poly(N isopropylacrylamide) (PNIPAAm) and the pH and thermo responsive polymer poly((2-dimethylamino)ethyl methacrylate) (PDMAEMA) were conjugated to FhuA and the genetic variants via controlled radical polymerization (CRP) using grafting from technique. These polymers were chosen because they would provide stimuli handles in the resulting membranes. The reported polymerization was the first ever attempt to attach polymer chains onto a membrane protein using site specific modification.
The conjugate synthesis was carried out in two steps – a) FhuA was first converted into a macroinitiator by covalently linking a water soluble functional CRP initiator to the lysine residues. b) Copper mediated CRP was then carried out in pure buffer conditions with and without sacrificial initiator to generate the conjugates.
The challenge was carrying out the modifications on FhuA without denaturing it. FhuA, being a transmembrane protein, requires amphiphilic species to stabilize its highly hydrophobic transmembrane region. For the experiments reported in this thesis, the stabilizing agent was 2 methyl 2,4-pentanediol (MPD). Since the buffer containing MPD cannot be considered a purely aqueous system, and also because MPD might interfere with the polymerization procedure, the reaction conditions were first optimized using a model globular protein, bovine serum albumin (BSA). The optimum conditions were then used for the generation of conjugates with FhuA.
The generated conjugates were shown to be highly interfacially active and this property was exploited to let them self assemble onto polar apolar interfaces. The emulsions stabilized by particles or conjugates are referred to as Pickering emulsions. Crosslinking conjugates with a UV crosslinkable co monomer afforded nano thin micro compartments. Interfacial self assembly at the air water interface and subsequent UV crosslinking also yielded nano thin, stimuli responsive membranes which were shown to be mechanically robust. Initial characterization of the flux and permeation of water through these membranes is also reported herein. The generated nano thin membranes with PNIPAAm showed reduced permeation at elevated temperatures owing to the resistance by the hydrophobic and thus water-impermeable polymer matrix, hence confirming the stimulus responsivity.
Additionally, as a part of collaborative work with Dr. Changzhu Wu, TU Dresden, conjugates of three enzymes with current/potential industrial relevance (candida antarctica lipase B, benzaldehyde lyase and glucose oxidase) with stimuli responsive polymers were synthesized. This work aims at carrying out cascade reactions in the Pickering emulsions generated by self assembled enzyme polymer conjugate.
The high interfacial activity of protein-polymer conjugates has inspired their use as stabilizers for Pickering emulsions, resulting in many interesting applications such as synthesis of templated micro-compartments and protocells or vehicles for drug and gene delivery. In this study we report, for the first time, the stabilization of Pickering emulsions with conjugates of a genetically modified transmembrane protein, ferric hydroxamate uptake protein component A (FhuA). The lysine residues of FhuA with open pore (FhuA Delta CVFtev) were modified to attach an initiator and consequently controlled radical polymerization (CRP) carried out via the grafting-from technique. The resulting conjugates of FhuA Delta CVFtev with poly(N-isopropylacrylamide) (PNIPAAm) and poly((2-dimethylamino) ethyl methacrylate) (PDMAEMA), the so-called building blocks based on transmembrane proteins (BBTP), have been shown to engender larger structures. The properties such as pH-responsivity, temperature-responsivity and interfacial activity of the BBTP were analyzed using UV-Vis spectrophotometry and pendant drop tensiometry. The BBTP were then utilized for the synthesis of highly stable Pickering emulsions, which could remain non-coalesced for well over a month. A new UV-crosslinkable monomer was synthesized and copolymerized with NIPAAm from the protein. The emulsion droplets, upon crosslinking of polymer chains, yielded micro-compartments. Fluorescence microscopy proved that these compartments are of micrometer scale, while cryo-scanning electron microscopy and scanning force microscopy analysis yielded a thickness in the range of 11.1 +/- 0.6 to 38.0 +/- 18.2 nm for the stabilizing layer of the conjugates. Such micro-compartments would prove to be beneficial in drug delivery applications, owing to the possibility of using the channel of the transmembrane protein as a gate and the smart polymer chains as trigger switches to tune the behavior of the capsules.
Porous polyelectrolyte membranes stable in a highly ionic environment are obtained by covalent crosslinking of an imidazolium-based poly(ionic liquid). The crosslinking reaction involves the UV light-induced thiol-ene (click) chemistry, and the phase separation, occurring during the crosslinking step, generates a fully interconnected porous structure in the membrane. The porosity is on the order of the micrometer scale and the membrane shows a gradient of pore size across the membrane cross-section. The membrane can separate polystyrene latex particles of different size and undergoes actuation in contact with acetone due to the asymmetric porous structure.
A new isoflavone, 8-prenylmilldrone (1), and four new rotenoids, oblarotenoids A-D (2-5), along with nine known compounds (6-14), were isolated from the CH2Cl2/CH3OH (1:1) extract of the leaves of Millettia oblata ssp. teitensis by chromatographic separation. The purified compounds were identified by NMR spectroscopic and mass spectrometric analyses, whereas the absolute configurations of the rotenoids were established on the basis of chiroptical data and in some cases by single-crystal X-ray crystallography. Maximaisoflavone J (11) and oblarotenoid C (4) showed weak activity against the human breast cancer cell line MDA-MB-231 with IC50 values of 33.3 and 93.8 mu M, respectively.
In this work, a sensor system based on thermoresponsive materials is developed by utilizing a modular approach. By synthesizing three different key monomers containing either a carboxyl, alkene or alkyne end group connected with a spacer to the methacrylic polymerizable unit, a flexible copolymerization strategy has been set up with oligo ethylene glycol methacrylates. This allows to tune the lower critical solution temperature (LCST) of the polymers in aqueous media. The molar masses are variable thanks to the excurse taken in polymerization in ionic liquids thus stretching molar masses from 25 to over 1000 kDa. The systems that were shown shown to be effective in aqueous solution could be immobilized on surfaces by copolymerizing photo crosslinkable units. The immobilized systems were formulated to give different layer thicknesses, swelling ratios and mesh sizes depending on the demand of the coupling reaction.
The coupling of detector units or model molecules is approached via reactions of the click chemistry pool, and the reactions are evaluated on their efficiency under those aspects, too. These coupling reactions are followed by surface plasmon resonance spectroscopy (SPR) to judge efficiency. With these tools at hand, Salmonella saccharides could be selectively detected by SPR. Influenza viruses were detected in solution by turbidimetry in solution as well as by a copolymerized solvatochromic dye to track binding via the changes of the polymers’ fluorescence by said binding event. This effect could also be achieved by utilizing the thermoresponsive behavior. Another demonstrator consists of the detection system bound to a quartz surface, thus allowing the virus detection on a solid carrier.
The experiments show the great potential of combining the concepts of thermoresponsive materials and click chemistry to develop technically simple sensors for large biomolecules and viruses.
Nowadays, the need to protect the environment becomes more urgent than ever. In the field of chemistry, this translates to practices such as waste prevention, use of renewable feedstocks, and catalysis; concepts based on the principles of green chemistry. Polymers are an important product in the chemical industry and are also in the focus of these changes. In this thesis, more sustainable approaches to make two classes of polymers, polypeptoids and polyesters, are described.
Polypeptoids or poly(alkyl-N-glycines) are isomers of polypeptides and are biocompatible, as well as degradable under biologically relevant conditions. In addition to that, they can have interesting properties such as lower critical solution temperature (LCST) behavior. They are usually synthesized by the ring opening polymerization (ROP) of N-carboxy anhydrides (NCAs), which are produced with the use of toxic compounds (e.g. phosgene) and which are highly sensitive to humidity. In order to avoid the direct synthesis and isolation of the NCAs, N-phenoxycarbonyl-protected N-substituted glycines are prepared, which can yield the NCAs in situ. The conditions for the NCA synthesis and its direct polymerization are investigated and optimized for the simplest N-substituted glycine, sarcosine. The use of a tertiary amine in less than stoichiometric amounts compared to the N-phenoxycarbonyl--sarcosine seems to accelerate drastically the NCA formation and does not affect the efficiency of the polymerization. In fact, well defined polysarcosines that comply to the monomer to initiator ratio can be produced by this method. This approach was also applied to other N-substituted glycines.
Dihydroxyacetone is a sustainable diol produced from glycerol, and has already been used for the synthesis of polycarbonates. Here, it was used as a comonomer for the synthesis of polyesters. However, the polymerization of dihydroxyacetone presented difficulties, probably due to the insolubility of the macromolecular chains. To circumvent the problem, the dimethyl acetal protected dihydroxyacetone was polymerized with terephthaloyl chloride to yield a soluble polymer. When the carbonyl was recovered after deprotection, the product was insoluble in all solvents, showing that the carbonyl in the main chain hinders the dissolution of the polymers. The solubility issue can be avoided, when a 1:1 mixture of dihydroxyacetone/ ethylene glycol is used to yield a soluble copolyester.
Near edge X-ray absorption fine structure (NEXAFS) simulations based on the conventional configuration interaction singles (CIS) lead to excitation energies, which are systematically blue shifted. Using a (restricted) open shell core hole reference instead of the Hartree Fock (HF) ground state orbitals improves (Decleva et al., Chem. Phys., 1992, 168, 51) excitation energies and the shape of the spectra significantly. In this work, we systematically vary the underlying SCF approaches, that is, based on HF or density functional theory, to identify best suited reference orbitals using a series of small test molecules. We compare the energies of the K edges and NEXAFS spectra to experimental data. The main improvement compared to conventional CIS, that is, using HF ground state orbitals, is due to the electrostatic influence of the core hole. Different SCF approaches, density functionals, or the use of fractional occupations lead only to comparably small changes. Furthermore, to account for bigger systems, we adapt the core-valence separation for our approach. We demonstrate that the good quality of the spectrum is not influenced by this approximation when used together with the non-separated ground state wave function. Simultaneously, the computational demands are reduced remarkably. (C) 2016 Wiley Periodicals, Inc.
In dieser Arbeit werden drei Themen im Zusammenhang mit den spektroskopischen Eigenschaften von Cumarin- (Cou) und DBD-Farbstoffen ([1,3]Dioxolo[4,5-f][1,3]benzodioxol) behandelt. Der erste Teil zeigt die grundlegende spektroskopische Charakterisierung von 7-Aminocumarinen und ihre potentielle Anwendung als Fluoreszenzsonde für Fluoreszenzimmunassays. Im zweiten Teil werden mit die photophysikalischen Eigenschaften der Cumarine genutzt um Cou- und DBD-funktionalisierte Oligo-Spiro-Ketal-Stäbe (OSTK) und ihre Eigenschaften als Membransonden zu untersuchen. Der letzte Teil beschäftigt sich mit der Synthese und der Charakterisierung von Cou- und DBD-funktionalisierten Polyprolinen als Referenzsysteme für schwefelfunktionalisierte OSTK-Stäbe und ihrer Kopplung an Goldnanopartikel.
Immunochemische Analysemethoden sind in der klinischen Diagnostik sehr erfolgreich und werden heute auch für die Nahrungsmittelkontrolle und Überwachung von Umweltfragen mit einbezogen. Dadurch sind sie von großem Interesse für weitere Forschungen. Unter den verschiedenen Immunassays zeichnen sich lumineszenzbasierte Formate durch ihre herausragende Sensitivität aus, die dieses Format für zukünftige Anwendungen besonders attraktiv macht. Die Notwendigkeit von Multiparameterdetektionsmöglichkeiten erfordert einen Werkzeugkasten mit Farbstoffen, um die biochemische Reaktion in ein optisch detektierbares Signal umzuwandeln. Hier wird bei einem Multiparameteransatz jeder Analyt durch einen anderen Farbstoff mit einer einzigartigen Emissionsfarbe, die den blauen bis roten Spektralbereich abdecken, oder eine einzigartige Abklingzeit detektiert. Im Falle eines kompetitiven Immunassayformats wäre für jeden der verschiedenen Farbstoffe ein einzelner Antikörper erforderlich. In der vorliegenden Arbeit wird ein leicht modifizierter Ansatz unter Verwendung einer Cumarineinheit, gegen die hochspezifische monoklonale Antikörper (mAb) erzeugt wurden, als grundlegendes Antigen präsentiert. Durch eine Modifikation der Stammcumarineinheit an einer Position des Moleküls, die für die Erkennung durch den Antikörper nicht relevant ist, kann auf den vollen Spektralbereich von blau bis tiefrot zugegriffen werden. In dieser Arbeit wird die photophysikalische Charakterisierung der verschiedenen Cumarinderivate und ihrer entsprechenden Immunkomplexe mit zwei verschiedenen, aber dennoch hochspezifischen, Antikörpern präsentiert. Die Cumarinfarbstoffe und ihre Immunkomplexe wurden durch stationäre und zeitaufgelöste Absorptions- sowie Fluoreszenzemissionsspektroskopie charakterisiert. Darüber hinaus wurden Fluoreszenzdepolarisationsmessungen durchgeführt, um die Daten zu vervollständigen, die die verschiedenen Bindungsmodi der beiden Antikörper betonten. Im Gegensatz zu häufig eingesetzten Nachweissystemen wurde eine massive Fluoreszenzverstärkung bei der Bildung des Antikörper-Farbstoffkomplexes bis zu einem Faktor von 50 gefunden. Wegen der leichten Emissionsfarbenänderung durch das Anpassen der Cumarinsubstitution in der für die Antigenbindung nicht relevanten Position des Elternmoleküls, ist eine Farbstoff-Toolbox vorhanden, die bei der Konstruktion von kompetitiven Multiparameterfluoreszenzverstärkungsimmunassays verwendet werden kann.
Oligo-Spiro-Thio-Ketal-Stäbe werden aufgrund ihres hydrophoben Rückgrats leicht in Doppellipidschichten eingebaut und deshalb als optische Membransonde verwendet. Wegen ihres geringen Durchmessers wird nur eine minimale Störung der Doppellipidschicht verursacht. Durch die Markierung mit Fluoreszenzfarbstoffen sind neuartige Förster-Resonanz-Energietransfersonden mit hoch definierten relativen Orientierungen der Übergangsdipolmomente der Donor- und Akzeptorfarbstoffe zugänglich und macht die Klasse der OSTK-Sonden zu einem leistungsstarken, flexiblen Werkzeugkasten für optische Biosensoranwendungen. Mit Hilfe von stationären und zeitaufgelösten Fluoreszenzexperimenten wurde der Einbau von Cumarin- und DBD markierten OSTK-Stäben in großen unilamellaren Vesikeln untersucht und die Ergebnisse durch Fluoreszenzdepolarisationsmessungen untermauert.
Der letzte Teil dieser Arbeit beschäftigt sich mit der Synthese und Charakterisierung von Cou- und DBD-funktionalisierten Polyprolinen und ihrer Kopplung an Goldnanopartikel. Die farbstoffmarkierten Polyproline konnten erfolgreich hergestellt werden. Es zeigten sich deutlich Einflüsse auf die spektroskopischen Eigenschaften der Farbstoffe durch die Bindung an die Polyprolinhelix. Die Kopplung an die 5 nm großen AuNP konnte erfolgreich durchgeführt werden. Die Erfahrungen, die durch die Kopplung der Polyproline an die AuNP, gewonnen wurde, ist die Basis für eine Einzelmolekül-AFM-FRET-Nanoskopie mit OSTK-Stäben.
A series of new fluorescent dye bearing monomers, including glycomonomers, based on maleamide and maleic esteramide was synthesized. The dye monomers were incorporated by radical copolymerization into thermo-responsive poly(N-vinyl-caprolactam) that displays a lower critical solution temperature (LCST) in aqueous solution. The effects of the local molecular environment on the polymers' luminescence, in particular on the fluorescence intensity and the extent of solvatochromism, were investigated below as well as above the phase transition. By attaching substituents of varying size and polarity in the close vicinity of the fluorophore, and by varying the spacer groups connecting the dyes to the polymer backbone, we explored the underlying structure-property relationships, in order to establish rules for successful sensor designs, e.g., for molecular thermometers. Most importantly, spacer groups of sufficient length separating the fluorophore from the polymer backbone proved to be crucial for obtaining pronounced temperature regulated fluorescence responses.
Reversible movements of current polymeric actuators stem from the continuous response to signals from a controlling unit, and subsequently cannot be interrupted without stopping or eliminating the input trigger. Here, we present actuators based on cross-linked blends of two crystallizable polymers capable of pausing their movements in a defined manner upon continuous cyclic heating and cooling. This noncontinuous actuation can be adjusted by varying the applied heating and cooling rates. The feasibility of these devices for technological applications was shown in a 140 cycle experiment of free-standing noncontinuous shape shifts, as well as by various demonstrators.
Synthesis of Pyridylanthracenes and Their Reversible Reaction with Singlet Oxygen to Endoperoxides
(2017)
The ortho, meta, and para isomers of 9,10-dipyridylanthracene 1 have been synthesized and converted into their endoperoxides 1-O-2 upon oxidation with singlet oxygen. The kinetics of this reaction can be controlled by the substitution pattern and the solvent: in highly polar solvents, the meta isomer is the most reactive, whereas the ortho isomer is oxidized fastest in nonpolar solvents. Heating of the endoperoxides affords the parent anthracenes by release of singlet oxygen.
Carbohydrates carrying thiol groups at the C-2 position have been attached to gold nanoparticles (AuNPs) with stereocenters in close proximity to the surface for the first time. Their configurations can be clearly distinguished by the tendency of particle aggregation. AuNP surface plasmon resonance (SPR), X-ray photoelectron spectroscopy (XPS), and IR spectroscopy indicate that the thiocarbohydrates replace citrate molecules at different rates, causing aggregation and eventually precipitation. A quantitative formulation of this aggregation process shows that reactivities can vary by several magnitudes. Adsorption isotherms and kinetics also demonstrate that the number of thiocarbohydrates varies by a factor of two. Molecular mechanics force field (MMFF) calculations reveal their relative orientations. Based on these models, the different binding behavior can be ascribed to attractive van der Waals forces and hydrogen bonds. Such interactions occur either between the carbohydrate and AuNPs, by lateral intermolecular forces at the surface, or by interparticle attraction, in analogy to cell-surface carbohydrates of biological recognition systems. Aggregation of NPs therefore act as an indicator to differentiate between various carbohydrates with defined configurations.
Magnetosome Organization in Magnetotactic Bacteria Unraveled by Ferromagnetic Resonance Spectroscopy
(2017)
Magnetotactic bacteria form assemblies of magnetic nanoparticles called magnetosomes. These magnetosomes are typically arranged in chains, but other forms of assemblies such as clusters can be observed in some species and genetic mutants. As such, the bacteria have developed as a model for the understanding of how organization of particles can influence the magnetic properties. Here, we use ferromagnetic resonance spectroscopy to measure the magnetic anisotropies in different strains of Magnetosprillum gtyphiswaldense MSR-1, a bacterial species that is amendable to genetic mutations. We combine our experimental results with a model describing the spectra. The model includes chain imperfections and misalignments following a Fisher distribution function, in addition to the intrinsic magnetic properties of the magnetosomes. Therefore, by applying the model to analyze the ferromagnetic resonance data, the distribution of orientations in the bulk sample can be retrieved in addition to the average magnetosome arrangement. In this way, we quantitatively characterize the magnetosome arrangement in both wild-type cells and Delta mamJ mutants, which exhibit differing magnetosome organization.
A variety of azobenzenes were synthesized to study the behavior of their E and Z isomers upon electrochemical reduction. Our results show that the radical anion of the Z isomer is able to rapidly isomerize to the corresponding E configured counterpart with a dramatically enhanced rate as compared to the neutral species. Due to a subsequent electron transfer from the formed E radical anion to the neutral Z starting material the overall transformation is catalytic in electrons; i.e., a substoichiometric amount of reduced species can isomerize the entire mixture. This pathway greatly increases the efficiency of (photo)switching while also allowing one to reach photostationary state compositions that are not restricted to the spectral separation of the individual azobenzene isomers and their quantum yields. In addition, activating this radical isomerization pathway with photoelectron transfer agents allows us to override the intrinsic properties of an azobenzene species by triggering the reverse isomerization direction (Z -> E) by the same wavelength of light, which normally triggers E -> Z isomerization. The behavior we report appears to be general, implying that the metastable isomer of a photoswitch can be isomerized to the more stable one catalytically upon reduction, permitting the optimization of azobenzene switching in new as well as indirect ways.
Lignin valorization
(2017)
The topic of this project is the use of lignin as alternative source of aromatic building blocks and oligomers to fossil feedstocks. Lignin is known as the most abundant aromatic polymer in nature and is isolated from the lignocellulosic component of plants by different possible extraction treatments. Both the biomass source and the extraction method affect the structure of the isolated lignin, therefore influencing its further application. Lignin was extracted from beech wood by two different hydrothermal alkaline treatments, which use NaOH and Ba(OH)2 as base and by an acid-catalyzed organosolv process. Moreover, lignin was isolated from bamboo, beech wood and coconut by soda treatment of the biomasses. A comparison of the structural features of such isolated lignins was performed through the use of a wide range of analytical methods. Alkaline lignins resulted in a better candidate as carbon precursor and macromonomers for the synthesis of polymer than organosolv lignin. In fact, alkaline lignins showed higher residual mass after carbonization and higher content of the reactive hydroxy functionalities. In contrast, the lignin source turned out to slightly affect the lignin hydroxyl content.
One of the most common lignin modifications is its deconstruction to obtain aromatic molecules, which can be used as starting materials for the synthesis of fine chemicals. Lignin deconstruction leads to a complex mixture of aromatic molecules. A gas chromatographic analytical method was developed to characterize the mixture of products obtained by lignin deconstruction via heterogeneous catalytic hydrogenolysis. The analytical protocol allowed the quantification of three main groups of molecules by means of calibration curves, internal standard and a preliminary silylation step of the sample. The analytical method was used to study the influence of the hydrogenolysis catalyst, temperature and system (flow and batch reactor) on the yield and selectivity of the aromatic compounds.
Lignin extracted from beech wood by a hydrothermal process using Ba(OH)2 as base, was functionalized by aromatic nitration in order to add nitrogen functionalities. The final goal was the synthesis of a nitrogen doped carbon. Nitrated lignin was reduced to the amino form in order to compare the influence of different nitrogen functionalities on the porosity of the final carbon. The carbons were obtained by ionothermal treatment of the precursors in the presence of the eutectic salt mixture KCl/ZnCl2 Such synthesized carbons showed micro-, macro- and mesoporosity and were tested for their electrocatalytic activity towards the oxygen reduction reaction. Mesoporous carbon derived from nitro lignin displayed the highest electrocatalytic activity.
Lignins isolated from coconut, beech wood and bamboo were used as macromonomers for the synthesis of biobased polyesters. A condensation reaction was performed between lignin and a hyper branched poly(ester-amine), previously obtained by condensation of triethanolamine and adipic acid. The influence of the lignin source and content on the thermochemical and mechanical properties of the final material was investigated. The prepolymer showed adhesive properties towards aluminum and its shear strength was therefore measured. The gluing properties of such synthesized glues turned out to be independent from the lignin source but affected by the amount of lignin in the final material.
This work shows that, although still at a laboratory scale, the valorization of lignin can overcome the critical issues of lignin´s structure variability and complexity.
Deprotonation of ligand-appended alkoxyl groups in mononuclear copper(II) complexes of N,O ligands L-1 and L-2, gave dinuclear complexes sharing symmetrical Cu2O2 cores. Molecular structures of these mono-and binuclear complexes have been characterized by XRD, and their electronic structures by UV/Vis, H-1 NMR, EPR and DFT; moreover, catalytic performance as models of catechol oxidase was studied. The binuclear complexes with anti-ferromagnetically coupled copper(II) centers are moderately active in quinone formation from 3,5-di-tert-butyl-catechol under the estab-lished conditions of oxygen saturation, but are strongly activated when additional dioxygen is administered during catalytic turnover. This unforeseen and unprecedented effect is attributed to increased maximum reaction rates v(max), whereas the substrate affinity KM remains unaffected. Oxygen administration is capable of (partially) removing limitations to turnover caused by product inhibition. Because product inhibition is generally accepted to be a major limitation of catechol oxidase models, we think that our observations will be applicable more widely.
Noninvasive imaging in the root soil compartment is mandatory for improving knowledge about root soil interactions and uptake processes which eventually control crop growth and productivity. Here we propose a method of MRI T-1 relaxation mapping to investigate water uptake patterns, and as second example, in combination with neutron tomography (NT), property changes in the rhizosphere. The first part demonstrates quantification of solute enrichment by advective transport to the roots due to water uptake. This accumulation is counterbalanced by net downward flow and dispersive spreading. One can furthermore discriminate between zones of high accumulation patterns and zones with much less enrichment. This behavior persists over days. The second part presents the novel combination of MRI with neutron tomography to couple static, proton density information of roots and their interface to the surrounding soil with information about the local water dynamics, reflected by NMR relaxation times. The root soil interface of a broad bean plant is characterized by slightly increasing MRI and NT signal intensity but decreasing T-1 relaxation time indicating locally changed soil properties.
Materials based on biodegradable polyesters, such as poly(butylene terephthalate) (PBT) or poly(butylene terephthalate-co-poly(alkylene glycol) terephthalate) (PBTAT), have potential application as pro-regenerative scaffolds for bone tissue engineering. Herein, the preparation of films composed of PBT or PBTAT and an engineered spider silk protein, (eADF4(C16)), that displays multiple carboxylic acid moieties capable of binding calcium ions and facilitating their biomineralization with calcium carbonate or calcium phosphate is reported. Human mesenchymal stem cells cultured on films mineralized with calcium phosphate show enhanced levels of alkaline phosphatase activity suggesting that such composites have potential use for bone tissue engineering.
Photonic sensing in highly concentrated biotechnical processes by photon density wave spectroscopy
(2017)
Photon Density Wave (PDW) spectroscopy is introduced as a new approach for photonic sensing in highly concentrated biotechnical processes. It independently quantifies the absorption and reduced scattering coefficient calibration-free and as a function of time, thus describing the optical properties in the vis/NIR range of the biomaterial during their processing. As examples of industrial relevance, enzymatic milk coagulation, beer mashing, and algae cultivation in photo bioreactors are discussed.
Nanolenses are linear chains of differently-sized metal nanoparticles, which can theoretically provide extremely high field enhancements. The complex structure renders their synthesis challenging and has hampered closer analyses so far. Here, the technique of DNA origami was used to self-assemble DNA-coated 10 nm, 20 nm, and 60 nm gold or silver nanoparticles into gold or silver nanolenses. Three different geometrical arrangements of gold nanolenses were assembled, and for each of the three, sets of single gold nanolenses were investigated in detail by atomic force microscopy, scanning electron microscopy, dark-field scattering and Raman spectroscopy. The surface-enhanced Raman scattering (SERS) capabilities of the single nanolenses were assessed by labelling the 10 nm gold nanoparticle selectively with dye molecules. The experimental data was complemented by finite-difference time-domain simulations. For those gold nanolenses which showed the strongest field enhancement, SERS signals from the two different internal gaps were compared by selectively placing probe dyes on the 20 nm or 60 nm gold particles. The highest enhancement was found for the gap between the 20 nm and 10 nm nanoparticle, which is indicative of a cascaded field enhancement. The protein streptavidin was labelled with alkyne groups and served as a biological model analyte, bound between the 20 nm and 10 nm particle of silver nanolenses. Thereby, a SERS signal from a single streptavidin could be detected. Background peaks observed in SERS measurements on single silver nanolenses could be attributed to amorphous carbon. It was shown that the amorphous carbon is generated in situ.
Nanolenses are self-similar chains of metal nanoparticles, which can theoretically provide extremely high field enhancements. Yet, the complex structure renders their synthesis challenging and has hampered closer analyses so far. Here, DNA origami is used to self-assemble 10, 20, and 60 nm gold nanoparticles as plasmonic gold nanolenses (AuNLs) in solution and in billions of copies. Three different geometrical arrangements are assembled, and for each of the three designs, surface-enhanced Raman scattering (SERS) capabilities of single AuNLs are assessed. For the design which shows the best properties, SERS signals from the two different internal gaps are compared by selectively placing probe dyes. The highest Raman enhancement is found for the gap between the small and medium nanoparticle, which is indicative of a cascaded field enhancement.
Magnetische Eisenoxidnanopartikel werden bereits seit geraumer Zeit erfolgreich als MRT-Kontrastmittel in der klinischen Bildgebung eingesetzt. Durch Optimierung der magnetischen Eigenschaften der Nanopartikel kann die Aussagekraft von MR-Aufnahmen verbessert und somit der diagnostische Wert einer MR-Anwendung weiter erhöht werden. Neben der Verbesserung bestehender Verfahren wird die bildgebende Diagnostik ebenso durch die Entwicklung neuer Verfahren, wie dem Magnetic Particle Imaging, vorangetrieben. Da hierbei das Messsignal von den magnetischen Nanopartikeln selbst erzeugt wird, birgt das MPI einen enormen Vorteil hinsichtlich der Sensitivität bei gleichzeitig hoher zeitlicher und räumlicher Auflösung. Da es aktuell jedoch keinen kommerziell vertriebenen in vivo-tauglichen MPI-Tracer gibt, besteht ein dringender Bedarf an geeigneten innovativen Tracermaterialien. Daraus resultierte die Motivation dieser Arbeit biokompatible und superparamagnetische Eisenoxidnanopartikel für den Einsatz als in vivo-Diagnostikum insbesondere im Magnetic Particle Imaging zu entwickeln. Auch wenn der Fokus auf der Tracerentwicklung für das MPI lag, wurde ebenso die MR-Performance bewertet, da geeignete Partikel somit alternativ oder zusätzlich als MR-Kontrastmittel mit verbesserten Kontrasteigenschaften eingesetzt werden könnten.
Die Synthese der Eisenoxidnanopartikel erfolgte über die partielle Oxidation von gefälltem Eisen(II)-hydroxid und Green Rust sowie eine diffusionskontrollierte Kopräzipitation in einem Hydrogel.
Mit der partiellen Oxidation von Eisen(II)-hydroxid und Green Rust konnten erfolgreich biokompatible und über lange Zeit stabile Eisenoxidnanopartikel synthetisiert werden. Zudem wurden geeignete Methoden zur Formulierung und Sterilisierung etabliert, wodurch zahlreiche Voraussetzungen für eine Anwendung als in vivo-Diagnostikum geschaffen wurden. Weiterhin ist auf Grundlage der MPS-Performance eine hervorragende Eignung dieser Partikel als MPI-Tracer zu erwarten, wodurch die Weiterentwicklung der MPI-Technologie maßgeblich vorangetrieben werden könnte. Die Bestimmung der NMR-Relaxivitäten sowie ein initialer in vivo-Versuch zeigten zudem das große Potential der formulierten Nanopartikelsuspensionen als MRT-Kontrastmittel. Die Modifizierung der Partikeloberfläche ermöglicht ferner die Herstellung zielgerichteter Nanopartikel sowie die Markierung von Zellen, wodurch das mögliche Anwendungsspektrum maßgeblich erweitert wurde.
Im zweiten Teil wurden Partikel durch eine diffusionskontrollierte Kopräzipitation im Hydrogel, wobei es sich um eine bioinspirierte Modifikation der klassischen Kopräzipitation handelt, synthetisiert, wodurch Partikel mit einer durchschnittlichen Kristallitgröße von 24 nm generiert werden konnten. Die Bestimmung der MPS- und MR-Performance elektrostatisch stabilisierter Partikel ergab vielversprechende Resultate. In Vorbereitung auf die Entwicklung eines in vivo-Diagnostikums wurden die Partikel anschließend erfolgreich sterisch stabilisiert, wodurch der kolloidale Zustand in MilliQ-Wasser über lange Zeit aufrechterhalten werden konnte. Durch Zentrifugation konnten die Partikel zudem erfolgreich in verschiedene Größenfraktionen aufgetrennt werden. Dies ermöglichte die Bestimmung der idealen Aggregatgröße dieses Partikelsystems in Bezug auf die MPS-Performance.
In der vorliegenden Arbeit konnte gezeigt werden, dass die beiden verwendeten Amphiphile mit Cholesterol als hydrophoben Block, gute Template für die Mineralisation von Calciumphosphat an der Wasser/Luft-Grenzfläche sind. Mittels Infrarot-Reflexions-Absorptions-Spektroskopie (IRRAS), Röntgenphotoelektronenspektroskopie (XPS), Energie dispersiver Röntgenspektroskopie (EDXS), Elektronenbeugung (SAED) und hochauflösende Transmissionselektronenmikroskopie (HRTEM) konnte die erfolgreiche Mineralisation von Calciumphosphat für beide Amphiphile an der Wasser/Luft-Grenzfläche nachgewiesen werden. Es konnte auch gezeigt werden, dass das Phasenverhalten der beiden Amphiphile und die bei der Mineralisation von Calciumphosphat gebildeten Kristallphasen nicht identisch sind. Beide Amphiphile üben demnach einen unterschiedlichen Einfluss auf den Mineralisationsverlauf aus.
Beim CHOL-HEM konnte sowohl nach 3 h als auch nach 5 h Octacalciumphosphat (OCP) als einzige Kristallphase mittels XPS, SAED, HRTEM und EDXS nachgewiesen werden. Das A-CHOL hingegen zeigte bei der Mineralisation von Calciumphosphat nach 1 h zunächst eine nicht eindeutig identifizierbare Vorläuferphase aus amorphen Calciumphosphat, Brushit (DCPD) oder OCP. Diese wandelte sich dann nach 3 h und 5 h in ein Gemisch, bestehend aus OCP und ein wenig Hydroxylapatit (HAP) um.
Die Schlussfolgerung daraus ist, dass das CHOL-HEM in der Lage ist, dass während der Mineralisation entstandene OCP zu stabilisieren. Dies geschieht vermutlich durch die Adsorption des Amphiphils bevorzugt an der OCP Oberfläche in [100] Orientierung. Dadurch wird die Spaltung entlang der c-Achse unterdrückt und die Hydrolyse zum HAP verhindert.
Das A-CHOL ist hingegen sterisch anspruchsvoller und kann wahrscheinlich aufgrund seiner Größe nicht so gut an der OCP Kristalloberfläche adsorbieren verglichen zum CHOL HEM. Das CHOL-HEM kann also die Hydrolyse von OCP zu HAP besser unterdrücken als das A-CHOL. Da jedoch auch beim A-CHOL nach einer Mineralisationszeit von 5 h nur wenig HAP zu finden ist, wäre auch hier ein Stabilisierungseffekt der OCP Kristalle möglich. Um eine genaue Aussage darüber treffen zu können, sind jedoch zusätzliche Kontrollexperimente notwendig. Es wäre zum einen denkbar, die Mineralisationsexperimente über einen längeren Zeitraum durchzuführen. Diese könnten zeigen, ob das CHOL-HEM die Hydrolyse vom OCP zum HAP komplett unterdrückt. Außerdem könnte nachgewiesen werden, ob beim A-CHOL das OCP weiter zum HAP umgesetzt wird oder ob ein Gemisch beider Kristallphasen erhalten bleibt.
Um die Mineralisation an der Wasser/Luft-Grenzfläche mit der Mineralisation in Bulklösung zu vergleichen, wurden zusätzlich Mineralisationsexperimente in Bulklösung durchgeführt. Dazu wurden Nitrilotriessigsäure (NTA) und Ethylendiamintetraessigsäure (EDTA) als Mineralisationsadditive verwendet, da NTA unter anderem der Struktur der hydrophilen Kopfgruppe des A-CHOLs ähnelt. Es konnte gezeigt werden, dass ein Vergleich der Mineralisation an der Grenzfläche mit der Mineralisation in Bulklösung nicht ohne weiteres möglich ist. Bei der Mineralisation in Bulklösung wird bei tiefen pH-Werten DCPD und bei höheren pH-Werten HAP gebildet. Diese wurde mittels Röntgenpulverdiffraktometrie Messungen nachgewiesen und durch Infrarotspektroskopie bekräftigt. Die Bildung von OCP wie an der Wasser/Luft-Grenzfläche konnte nicht beobachtet werden.
Es konnte auch gezeigt werden, dass beide Additive NTA und EDTA einen unterschiedlichen Einfluss auf den Verlauf der Mineralisation nehmen. So unterscheiden sich zum einen die Morphologien des gebildeten DCPDs und zum anderen wurde beispielsweise in Anwesenheit von 10 und 15 mM NTA neben DCPD auch HAP bei einem Ausgangs-pH-Wert von 7 nachgewiesen.
Da unser Augenmerk speziell auf der Mineralisation von Calciumphosphat an der Wasser/Luft-Grenzfläche liegt, könnten Folgeexperimente wie beispielsweise GIXD Messungen durchgeführt werden. Dadurch wäre es möglich, einen Überblick über die gebildeten Kristallphasen nach unterschiedlichen Reaktionszeiten direkt auf dem Trog zu erhalten.
Es konnte weiterhin gezeigt werden, dass auch einfache Amphiphile in der Lage sind, die Mineralisation von Calciumphosphat zu steuern. Amphiphile mit Cholesterol als hydrophoben Block bilden offensichtlich besonders stabile Monolagen an der Wasser/Luft-Grenzfläche. Eine Untersuchung des Einflusses ähnlicher Amphiphile mit unterschiedlichen hydrophilen Kopfgruppen auf das Mineralisationsverhalten von Calciumphosphat wäre durchaus interessant.
Cholesteryl Hemisuccinate Monolayers Efficiently Control Calcium Phosphate Nucleation and Growth
(2017)
The article describes the phase behavior of cholesteryl hemisuccinate at the air-liquid interface and its effect on calcium phosphate (CP) mineralization. The amphiphile forms stable monolayers with phase transitions at the air-liquid interface from a gas to a tilted liquid-condensed (TLC) and finally to an untilted liquid-condensed (ULC) phase. CP mineralization beneath these monolayers leads to crumpled CP layers made from individual plates. The main crystal phase is octacalcium phosphate (OCP) along with a minor fraction of hydroxyapatite (HAP), as confirmed by X-ray photoelectron spectroscopy, energy dispersive X-ray spectroscopy, bright field transmission electron microscopy, and electron diffraction.
Die Verwendung von QR-Codes in Begleitseminaren zur Vorlesung „Organische Chemie“ für Studierende mit Chemie im Nebenfach wird vorgestellt. Die Hausaufgaben zu den Seminaren wurden mit einem QR-Code versehen. Dieser führt zu weiterführenden Hilfen. Der Einsatz der QR-Codes sowie die Neukonzeption der Seminare wurden evaluiert.
A series of new sulfobetaine methacrylates, including nitrogen-containing saturated heterocycles, was synthesised by systematically varying the substituents of the zwitterionic group. Radical polymerisation via the RAFT (reversible addition–fragmentation chain transfer) method in trifluoroethanol proceeded smoothly and was well controlled, yielding polymers with predictable molar masses. Molar mass analysis and control of the end-group fidelity were facilitated by end-group labeling with a fluorescent dye. The polymers showed distinct thermo-responsive behaviour of the UCST (upper critical solution temperature) type in an aqueous solution, which could not be simply correlated to their molecular structure via an incremental analysis of the hydrophilic and hydrophobic elements incorporated within them. Increasing the spacer length separating the ammonium and the sulfonate groups of the zwitterion moiety from three to four carbons increased the phase transition temperatures markedly, whereas increasing the length of the spacer separating the ammonium group and the carboxylate ester group on the backbone from two to three carbons provoked the opposite effect. Moreover, the phase transition temperatures of the analogous polyzwitterions decreased in the order dimethylammonio > morpholinio > piperidinio alkanesulfonates. In addition to the basic effect of the polymers’ precise molecular structure, the concentration and the molar mass dependence of the phase transition temperatures were studied. Furthermore, we investigated the influence of added low molar mass salts on the aqueous-phase behaviour for sodium chloride and sodium bromide as well as sodium and ammonium sulfate. The strong effects evolved in a complex way with the salt concentration. The strength of these effects depended on the nature of the anion added, increasing in the order sulfate < chloride < bromide, thus following the empirical Hofmeister series. In contrast, no significant differences were observed when changing the cation, i.e. when adding sodium or ammonium sulfate.
The tissue integration of synthetic polymers can be promoted by displaying RGD peptides at the biointerface with the objective of enhancing colonization of the material by endogenous cells. A firm but flexible attachment of the peptide to the polymer matrix, still allowing interaction with receptors, is therefore of interest. Here, the covalent coupling of flexible physical anchor groups, allowing for temporary immobilization on polymeric surfaces via hydrophobic or dipole-dipole interactions, to a RGD peptide was investigated. For this purpose, a stearate or an oligo(ethylene glycol) (OEG) was attached to GRGDS in 51-69% yield. The obtained RGD linker constructs were characterized by NMR, IR and MALDI-ToF mass spectrometry, revealing that the commercially available OEG and stearate linkers are in fact mixtures of similar compounds. The RGD linker constructs were co-electrospun with poly(p-dioxanone) (PPDO). After electrospinning, nitrogen could be detected on the surface of the PPDO fibers by X-ray photoelectron spectroscopy. The nitrogen content exceeded the calculated value for the homogeneous material mixture suggesting a pronounced presentation of the peptide on the fiber surface. Increasing amounts of RGD linker constructs in the electrospinning solution did not lead to a detection of an increased amount of peptide on the scaffold surface, suggesting inhomogeneous distribution of the peptide on the PPDO fiber surface. Human adipose-derived stem cells cultured on the patches showed similar viability as when cultured on PPDO containing pristine RGD. The fully characterized RGD linker constructs could serve as valuable tools for the further development of tissue-integrating polymeric scaffolds. Copyright (c) 2016 John Wiley & Sons, Ltd.
Four metal organic frameworks with similar topology but different chemical environment inside the pore structure, namely, IFP-1, IFP-3, IFP-5, and IFP-7, have been investigated with respect to the separation potential for olefin paraffin mixtures as well as the influence of the different linkers on adsorption properties using experiments and Monte Carlo simulations. All IFP structures show a higher adsorption of ethane compared to ethene with the exception of IFP-7 which shows no selectivity in breakthrough experiments. For propane/propane separation, all adsorbents show a higher adsorption for the olefin. The experimental results agree quite well with the simulated values except for the IFP-7, which is presumably due to the flexibility of the structure. Moreover, the experimental and simulated isotherms were confirmed with breakthrough experiments that render IFP-1, IFP-3, and IFP-5 as suitable for the purification of ethene from ethane.
In virtue of the rising demand for metal-free polymeric materials, organocatalytic polymerization has emerged and blossomed unprecedentedly in the past 15 years into an appealing research area and a powerful arsenal for polymer synthesis. In addition to the inherent merits as being metal-free, small molecule organocatalysts have also provided opportunities to develop alternative and, in many cases, more expedient synthetic approaches toward macromolecular architectures, that play a crucial role in shaping the properties of the obtained polymers. A majority of preliminary studies exploring for new catalysts, catalytic mechanisms and optimized polymerization conditions are extended to application of the catalytic systems on rational design and controlled synthesis of various macromolecular architectures. Such endeavors are described in this review, categorized by the architectural elements including chain structure (types, sequence and composition of monomeric units constituting the polymer chains), topological structure (the fashion different polymer chains are covalently attached to each other within the macromolecule) and functionality (position and amount of functional groups that endow the entire macromolecule with specific chemical, physico-chemical or biological properties). (C) 2017 Published by Elsevier B.V.
Editorial
(2017)
Herstellung anisotroper Kolloide mittels templatgesteuerter Assemblierung und Kontaktdruckverfahren
(2017)
Diese Arbeit befasste sich mit neuen Konzepten zur Darstellung anisotroper Partikelsysteme durch Anordnung von funktionalisierten Partikeln unter Zuhilfenahme etablierter Methoden wie der templatgestützten Assemblierung von Partikeln und dem Mikrokontaktdruck.
Das erste Teilprojekt beschäftigte sich mit der kontrollierten Herstellung von Faltenstrukturen im Mikro- bis Nanometerbereich. Die Faltenstrukturen entstehen durch die Relaxation eines Systems bestehend aus zwei übereinander liegender Schichten unterschiedlicher Elastizität. In diesem Fall wurden Falten auf einem elastischen PDMS-Substrat durch Generierung einer Oxidschicht auf der Substratoberfläche mittels Plasmabehandlung erzeugt. Die Dicke der Oxidschicht, die über verschiedene Parameter wie Behandlungszeit, Prozessleistung, Partialdruck des plasmaaktiven Gases, Vernetzungsgrad, Deformation sowie Substratdicke einstellbar war, bestimmte Wellenlänge und Amplitude der Falten.
Das zweite Teilprojekt hatte die Darstellung komplexer, kolloidaler Strukturen auf Basis supramolekularer Wechselwirkungen zum Ziel. Dazu sollte vor allem die templatgestützte Assemblierung von Partikeln sowohl an fest-flüssig als auch flüssig-flüssig Grenzflächen genutzt werden. Für Erstere sollten die in Teilprojekt 1 hergestellten Faltenstrukturen als Templat, für Letztere Pickering-Emulsionen zur Anwendung kommen. Im ersten Fall wurden verschiedene, modifizierte Silicapartikel und Magnetitnanopartikel, deren Größe und Oberflächenfunktionalität (Cyclodextrin-, Azobenzol- und Arylazopyrazolgruppen) variierte, in Faltenstrukturen angeordnet. Die Anordnung hing dabei nicht nur vom gewählten Verfahren, sondern auch von Faktoren wie der Partikelkonzentration, der Oberflächenladung oder dem Größenverhältnis der Partikel zur Faltengeometrie ab.
Die Kombination von Cyclodextrin (CD)- und Arylazopyrazol-modifizierten Partikeln ermöglichte, auf Basis einer Wirt-Gast-Wechselwirkung zwischen den Partikeltypen und einer templatgesteuerten Anordnung, die Bildung komplexer und strukturierter Formen in der Größenordnung mehrerer Mikrometer. Dieses System kann einerseits als Grundlage für die Herstellung verschiedener Janus-Partikel herangezogen werden, andererseits stellt die gerichtete Vernetzung zweier Partikelsysteme zu größeren Aggregaten den Grundstein für neuartige, funktionale Materialien dar. Neben der Anordnung an fest-flüssig Grenzflächen konnte außerdem nachgewiesen werden, dass Azobenzol-funktionalisierte Silicapartikel in der Lage sind, Pickering-Emulsionen über mehrere Monate zu stabilisieren. Die Stabilität und Größe der Emulsionsphase kann über Parameter, wie das Volumenverhältnis und die Konzentration, gesteuert werden. CD-funktionalisierte Silicapartikel besaßen dagegen keine Grenzflächenaktivität, während es CD-basierten Polymeren wiederum möglich war, durch die Ausbildung von Einschlusskomplexen mit den hydrophoben Molekülen der Ölphase stabile Emulsionen zu bilden. Dagegen zeigte die Kombination zwei verschiedener Partikelsysteme keinen oder einen destabilisierenden Effekt bezüglich der Ausbildung von Emulsionen.
Im letzten Teilprojekt wurde die Herstellung multivalenter Silicapartikel mittels Mikrokontaktdruck untersucht. Die Faltenstrukturen wurden dabei als Stempel verwendet, wodurch es möglich war, die Patch-Geometrie über die Wellenlänge der Faltenstrukturen zu steuern. Als Tinte diente das positiv geladene Polyelektrolyt Polyethylenimin (PEI), welches über elektrostatische Wechselwirkungen auf unmodifizierten Silicapartikeln haftet. Im Gegensatz zum Drucken mit flachen Stempeln fiel dabei zunächst auf, dass sich die Tinte bei den Faltenstrukturen nicht gleichmäßig über die gesamte Substratfläche verteilt, sondern hauptsächlich in den Faltentälern vorlag. Dadurch handelte es sich bei dem Druckprozess letztlich nicht mehr um ein klassisches Mikrokontaktdruckverfahren, sondern um ein Tiefdruckverfahren. Über das Tiefdruckverfahren war es dann aber möglich, sowohl eine als auch beide Partikelhemisphären gleichzeitig und mit verschiedenen Funktionalitäten zu modifizieren und somit multivalente Silicapartikel zu generieren. In Abhängigkeit der Wellenlänge der Falten konnten auf einer Partikelhemisphäre zwei bis acht Patches abgebildet werden. Für die Patch-Geometrie, sprich Größe und Form der Patches, spielten zudem die Konzentration der Tinte auf dem Stempel, das Lösungsmittel zum Ablösen der Partikel nach dem Drucken sowie die Stempelhärte eine wichtige Rolle. Da die Stempelhärte aufgrund der variierenden Dicke der Oxidschicht bei verschiedenen Wellenlängen nicht kontant ist, wurden für den Druckprozess meist Abgüsse der Faltensubstrate verwendet. Auf diese Weise war auch die Vergleichbarkeit bei variierender Wellenlänge gewährleistet. Neben dem erfolgreichen Nachweis der Modifikation mittels Tiefdruckverfahren konnte auch gezeigt werden, dass über die Komplexierung mit PEI negativ geladene Nanopartikel auf die Partikeloberfläche aufgebracht werden können.
Among modern functional materials, the class of nitrogen-containing carbons combines non-toxicity and sustainability with outstanding properties. The versatility of this materials class is based on the opportunity to tune electronic and catalytic properties via the nitrogen content and –motifs: This ranges from the electronically conducting N-doped carbon, where few carbon atoms in the graphitic lattice are substituted by nitrogen, to the organic semiconductor graphitic carbon nitride (g-C₃N₄), with a structure based on tri-s-triazine units.
In general, composites can reveal outstanding catalytic properties due to synergistic behavior, e.g. the formation of electronic heterojunctions. In this thesis, the formation of an “all-carbon” heterojunction was targeted, i.e. differences in the electronic properties of the single components were achieved by the introduction of different nitrogen motives into the carbon lattice. Such composites are promising as metal-free catalysts for the photocatalytic water splitting. Here, hydrogen can be generated from water by light irradiation with the use of a photocatalyst. As first part of the heterojunction, the organic semiconductor g-C₃N₄ was employed, because of its suitable band structure for photocatalytic water splitting, high stability and non-toxicity. The second part was chosen as C₂N, a recently discovered semiconductor. Compared to g-C₃N₄, the less nitrogen containing C₂N has a smaller band gap and a higher absorption coefficient in the visible light range, which is expected to increase the optical absorption in the composite eventually leading to an enhanced charge carrier separation due to the formation of an electronic heterojunction.
The aim of preparing an “all-carbon” composite included the research on appropriate precursors for the respective components g-C₃N₄ and C₂N, as well as strategies for appropriate structuring. This was targeted by applying precursors which can form supramolecular pre-organized structures. This allows for more control over morphology and atom patterns during the carbonization process.
In the first part of this thesis, it was demonstrated how the photocatalytic activity of g-C₃N₄ can be increased by the targeted introduction of defects or surface terminations. This was achieved by using caffeine as a “growth stopping” additive during the formation of the hydrogen-bonded supramolecular precursor complexes. The increased photocatalytic activity of the obtained materials was demonstrated with dye degradation experiments.
The second part of this thesis was focused on the synthesis of the second component C₂N. Here, a deep eutectic mixture from hexaketocyclohexane and urea was structured using the biopolymer chitosan. This scaffolding resulted in mesoporous nitrogen-doped carbon monoliths and beads. CO₂- and dye-adsorption experiments with the obtained monolith material revealed a high isosteric heat of CO₂-adsorption and showed the accessibility of the monolithic pore system to larger dye molecules. Furthermore, a novel precursor system for C₂N was explored, based on organic crystals from squaric acid and urea. The respective C₂N carbon with an unusual sheet-like morphology could be synthesized by carbonization of the crystals at 550 °C. With this precursor system, also microporous C₂N carbon with a BET surface area of 865 m²/g was obtained by “salt-templating” with ZnCl₂.
Finally, the preparation of a g-C₃N₄/C₂N “all carbon” composite heterojunction was attempted by the self-assembly of g-C₃N₄ and C₂N nanosheets and tested for photocatalytic water splitting. Indeed, the composites revealed high rates of hydrogen evolution when compared to bulk g-C₃N₄. However, the increased catalytic activity was mainly attributed to the high surface area of the nanocomposites rather than to the composition. With regard to alternative composite synthesis ways, first experiments indicated N-Methyl-2-pyrrolidon to be suitable for higher concentrated dispersion of C₂N nanosheets. Eventually, the results obtained in this thesis provide precious synthetic contributions towards the preparation and processing of carbon/nitrogen compounds for energy applications.
The Marangoni contraction of sessile drops of a binary mixture of a volatile and a nonvolatile liquid has been investigated experimentally and theoretically. The origin of the contraction is the locally inhomogeneous evaporation rate of sessile drops. This leads to surface tension gradients and thus to a Marangoni flow. Simulations show that the interplay of Marangoni flow, capillary flow, diffusive transport, and evaporative losses can establish a quasistationary drop profile with an apparent nonzero contact angle even if both liquid components individually wet the substrate completely. Experiments with different solvents, initial mass fractions, and gaseous environments reveal a previously unknown universal power-law relation between the apparent contact angle and the relative undersaturation of the ambient atmosphere: theta(app) similar to (RHeq - RH)(1/3). This experimentally observed power law is in quantitative agreement with simulation results. The exponent can also be inferred from a scaling analysis of the hydrodynamic-evaporative evolution equations of a binary mixture of liquids with different volatilities.
Fluorinating conjugated polymers is a proven strategy for creating high performance materials in polymer solar cells, yet few studies have investigated the importance of the fluorination method. We compare the performance of three fluorinated systems: a poly(benzodithieno-dithienyltriazole) (PBnDT-XTAZ) random copolymer where 50% of the acceptor units are difluorinated, PBnDT-mFTAZ where every acceptor unit is monofluorinated, and a 1:1 physical blend of the difluorinated and nonfluorinated polymer. All systems have the same degree of fluorination (50%) yet via different methods (chemically vs physically, random vs regular). We show that these three systems have equivalent photovoltaic behavior:,similar to 5.2% efficiency with a short-circuit current (J(sc)) at,similar to 11 mA cm(-2), an open-circuit voltage (v(oc)) at 0.77 V, and a fill factor (FF) of similar to 60%. Further investigation of these three systems demonstrates that the charge generation, charge extraction, and charge transfer state are essentially identical for the three studied systems. Transmission electron microscopy shows no significant differences in the morphologies. All these data illustrate that it is possible to improve performance not only via regular or random fluorination but also by physical addition via a ternary blend. Thus, our results demonstrate the versatility of incorporating fluorine in the active layer of polymer solar cells to enhance device performance.
Spot variation fluorescence correlation spectroscopy (SV-FCS) is a variant of the FCS techniques which may give useful information about the structural organisation of the medium in which the diffusion takes place. We show that the same results can be obtained by post-processing the photon count data from ordinary FCS measurements. By using this method, one obtains the fluorescence autocorrelation functions for sizes of confocal volume, which are effectively smaller than that of the initial FCS measurement. The photon counts of the initial experiment are first transformed into smooth intensity trace using kernel smoothing method or to a piecewise-continuous intensity trace using binning and then a non-linear transformation is applied to this trace. The result of this transformation mimics the photon count rate in an experiment performed with a smaller confocal volume. The applicability of the method is established in extensive numerical simulations and directly supported in in-vitro experiments. The procedure is then applied to the diffusion of AlexaFluor647-labeled streptavidin in living cells.
The conformational equilibrium of the axial/equatorial conformers of 4-methylene-cyclohexyl pivalate is studied by dynamic NMR spectroscopy in a methylene chloride/freon mixture. At 153K, the ring interconversion gets slow on the nuclear magnetic resonance timescale, the conformational equilibrium (-G degrees) can be examined, and the barrier to ring interconversion (G(#)) can be determined. The structural influence of sp(2) hybridization on both G degrees and G(#) of the cyclohexyl moiety can be quantified.
The spatial magnetic properties, through-space NMR shieldings (TSNMRS), of amino-substituted heteraromatic six-membered ring systems such as pyrylium/thiopyrylium analogues have been calculated using the GIAO perturbation method employing the nucleus independent chemical shift (NICS) concept and visualized as iso-chemical-shielding surfaces (ICSS) of various size and direction. The TSNMRS values were employed to quantify and visualize the existing aromaticity of the studied compounds. Due to strong conjugation of six-membered ring pi-electrons and lone pairs of the exo-cyclic amino substituents (restricted rotation about partial C,N double bonds) the interplay of still aromatic and already dominating trimethine cyanine/merocyanine-like substructures can be estimated. (C) 2017 Elsevier Ltd. All rights reserved.
para-Substituted benzoic acid esters of cyclohexanol, 1,4-dihydroxycyclohexane, 4-hydroxy-cyclohexanone and of the corresponding exo-methylene derivative were synthesized and the conformational equilibria of the cyclohexane skeleton studied by low temperature H-1 and C-13 NMR spectroscopy. The geometry optimized structures of the axial/equatorial chair conformers were computed at the DFT level of theory. Only one preferred conformation of the ester group was obtained for both the axial and the equatorial conformer, respectively. The content of the axial conformer increases with growing polarity of the 6-membered ring moiety; hereby, in addition, the effect of sp(2) hybridization/polarity of C(4)= O/C(4)= CH2 on the present conformational equilibria is critically evaluated. Another dynamic process could be studied, for the first time in this kind of compounds. (C) 2017 Elsevier Ltd. All rights reserved.
Molecular dynamics simulations in conjunction with the Martini coarse-grained model have been used to investigate the (nonequilibrium) behavior of helical 22-residue poly(gamma-benzyl-L-glutamate) (PBLG) peptides at the water/vapor interface. Preformed PBLG mono- or bilayers homogeneously covering the water surface laterally collapse in tens of nanoseconds, exposing significant proportions of empty water surface. This behavior was also observed in recent AFM experiments at similar areas per monomer, where a complete coverage had been assumed in earlier work. In the simulations, depending on the area per monomer, either elongated clusters or fibrils form, whose heights (together with the portion of empty water surface) increase over time. Peptides tend to align with respect to the fiber axis or with the major principal axis of the cluster, respectively. The aspect ratio of the cluster observed is 1.7 and, hence, comparable to though somewhat smaller than the aspect ratio of the peptides in alpha-helical conformation, which is 2.2. The heights of the fibrils is 3 nm after 20 ns and increases to 4.5 nm if the relaxation time is increased by 2 orders of magnitude, in agreement with the experiment. Aggregates with heights of about 3 or 4.5 nm are found to correspond to local bi- or trilayer structures, respectively.
In der vorliegenden Arbeit konnten erfolgreich zwei unterschiedliche Hybridmaterialien (HM) über die Sol-Gel-Methode synthetisiert werden. Bei den HM handelt es sich um Monolithe mit einem Durchmesser von bis zu 4,5 cm. Das erste HM besteht aus Titandioxid und Bombyx mori Seide und wird als TS bezeichnet, während das zweite weniger Seide und zusätzlich Polyethylenoxid (PEO) enthält und daher als TPS abgekürzt wird. Einige der HM wurden nach der Synthese in eine wässrige Tetrachloridogoldsäure-Lösung getaucht, wodurch sich auf der Oberfläche Goldnanopartikel gebildet haben.
Die Materialien wurden mittels Elektronenmikroskopie, energiedispersiver Röntgenspektroskopie, Ramanspektroskopie sowie Röntgenpulverdiffraktometrie charakterisiert. Die Ergebnisse zeigen, dass beide HM aus etwa 5 nm großen, sphärischen Titandioxidnanopartikeln aufgebaut sind, die primär aus Anatas und zu einem geringen Anteil aus Brookit bestehen. Die Goldnanopartikel bei TPS_Au waren größer und polydisperser als die Goldnanopartikel auf dem TS_Au HM. Darüber hinaus sind die Goldnanopartikel im TS HM tiefer in das Material eingedrungen als beim TPS HM.
Die weiterführende Analyse der HM mittels Elementaranalyse und thermogravimetrischer Analyse ergab für TPS einen geringeren Anteil an organischen Bestandteilen im HM als für TS, obwohl für beide Synthesen die gleiche Masse an organischen Materialien eingesetzt wurde. Es wird vermutet, dass das PEO während der Synthese teilweise wieder aus dem Material herausgewaschen wird. Diese Theorie korreliert mit den Ergebnissen aus der Stickstoffsorption und der Quecksilberporosimetrie, die für das TPS HM eine höhere Oberfläche als für das TS HM anzeigten.
Die Variation einiger Syntheseparameter wie die Menge an Seide und PEO oder die Zusammensetzung der Titandioxidvorläuferlösung hatte einen großen Einfluss auf die synthetisierten HM. Während unterschiedliche Mengen an PEO die Größe des HM beeinflussten, konnte ohne Seide kein HM in einer ähnlichen Größe hergestellt werden. Die Bildung der HM wird stark von der Zusammensetzung der Titandioxidvorläuferlösung beeinflusst. Eine Veränderung führte daher nur selten zur Bildung eines homogenen HM.
Die in dieser Arbeit synthetisierten HM wurden als Photokatalysatoren für die Wasserspaltung und den Abbau von Methylenblau eingesetzt. Bei der photokatalytischen Wasserspaltung wurde zunächst der Einfluss unterschiedlicher Goldkonzentrationen beim TPS HM auf die Wasserstoffausbeute untersucht. Die besten Ergebnisse wurden bei einer Menge von 2,5 mg Tetrachloridogoldsäure erhalten. Darüber hinaus wurde gezeigt, dass mit dem TPS HM eine deutlich höhere Menge an Wasserstoff gewonnen werden konnte als mit dem TS HM. Die Ursachen für die schlechtere Aktivität werden in der geringeren spezifischen Oberfläche, der unterschiedlichen Porenstruktur, dem höheren Anteil an Seide und besonders in der geringeren Größe und höheren Eindringtiefe der Goldnanopartikel vermutet. Darüber hinaus konnte mit einem höheren UV-Anteil in der Lichtquelle sowie durch die Zugabe von Ethanol als Opferreagenz eine Zunahme der Wasserstoffausbeute erzielt werden.
Bei dem Methylenblauabbau wurde für beide HM zunächst nur eine Adsorption des Methylenblaus beobachtet. Nach der Zugabe von Wasserstoffperoxid konnte nach 8 h bereits eine fast vollständige Oxidation des Methylenblaus unter sichtbarem Licht beobachtet werden. Die Ursache für die etwas höhere Aktivität von TPS gegenüber TS wird in der unterschiedlichen Porenstruktur und dem höheren Anteil an Seide im TS HM vermutet. Insgesamt zeigen beide HM eine gute photokatalytische Aktivität für den Abbau von Methylenblau im Vergleich zu den erhaltenen Werten aus der Literatur.
Planar bis(1,2-dithiooxalato)nickelate(II), [Ni(dto)]2− reacts in aqueous solutions with lanthanide ions (Ln3+) to form pentanuclear, hetero-bimetallic complexes of the general composition [{Ln(H2O)n}2{Ni(dto)2}3]·xH2O. (n = 4 or 5; x = 9–12). The complex [{Ho(H2O)5}2{Ni(dto)2}3]·10H2O, Ho2Ni3, was synthesized and characterized by single crystal X-ray structure analysis and powder diffraction. The Ho2Ni3 complex crystallizes as monoclinic crystals in the space group P21/c. The channels and cavities, appearing in the crystal packing of the complex molecules, are occupied by a varying amount of non-coordinated water molecules.
It is known that aqueous keratin hydrolysate solutions can be produced from feathers using superheated water as solvent. This method is optimized in this study by varying the time and temperature of the heat treatment in order to obtain a high solute content in the solution. With the dissolved polypeptides, films are produced using methyl cellulose as supporting material. Thereby, novel composite membranes are produced from bio-waste. It is expected that these materials exhibit both protein and polysaccharide properties. The influence of the embedded keratin hydrolysates on the methyl cellulose structure is investigated using Fourier transform infrared spectroscopy (FTIR) and wide angle X-ray diffraction (WAXD). Adsorption peaks of both components are present in the spectra of the membranes, while the X-ray analysis shows that the polypeptides are incorporated into the semi-crystalline methyl cellulose structure. This behavior significantly influences the mechanical properties of the composite films as is shown by tensile tests. Since further processing steps, e.g., crosslinking, may involve a heat treatment, thermogravimetric analysis (TGA) is applied to obtain information on the thermal stability of the composite materials.