A mechanistic perspective on plastically flexible coordination polymers

Mechanical flexibility in single crystals of covalently bound materials is a fascinating and poorly understood phenomenon. We present here the first example of a plastically flexible one‐dimensional (1D) coordination polymer. The compound [Zn(μ‐Cl)2(3,5‐dichloropyridine)2]n is flexible over two crystallographic faces. Remarkably, the single crystal remains intact when bent to 180°. A combination of microscopy, diffraction, and spectroscopic studies have been used to probe the structural response of the crystal lattice to mechanical bending. Deformation of the covalent polymer chains does not appear to be responsible for the observed macroscopic bending. Instead, our results suggest that mechanical bending occurs by displacement of the coordination polymer chains. Based on experimental and theoretical evidence, we propose a new model for mechanical flexibility in 1D coordination polymers. Moreover, our calculations propose a cause of the different mechanical properties of this compound and a structurally similar elastic material

Long-Time Behavior of Surface Properties of Microstructures Fabricated by Multiphoton Lithography

The multiphoton lithography (MPL) technique represents the future of 3D microprinting, enabling the production of complex microscale objects with high precision. Although the MPL fabrication parameters are widely evaluated and discussed, not much attention has been given to the microscopic properties of 3D objects with respect to their surface properties and time-dependent stability. These properties are of crucial importance when it comes to the safe and durable use of these structures in biomedical applications. In this work, we investigate the surface properties of the MPL-produced SZ2080 polymeric microstructures with regard to the physical aging processes during the post-production stage. The influence of aging on the polymeric microstructures was investigated by means of Atomic Force Microscopy (AFM) and X-ray Photoelectron Spectroscopy (XPS). As a result, a time-dependent change in Young’s Modulus, plastic deformation, and adhesion and their correlation to the development in chemical composition of the surface of MPL-microstructures are evaluated. The results presented here are valuable for the application of MPL-fabricated 3D objects in general, but especially in medical technology as they give detailed information of the physical and chemical time-dependent dynamic behavior of MPL-printed surfaces and thus their suitability and performance in biological systems.DFG, 457594480, Funktionale Polymer- und Nanokomposit-3D-Architekturen mittels Multi-PhotonenLaserstrukturierung für hochentwickelte Anwendungen in MikrobauelementenDFG, 232311024, Wirkprinzipien nanoskaliger Matrixadditive für den Faserverbundleichtba

Short- and Long-Range Mechanical and Chemical Interphases Caused by Interaction of Boehmite (γ-AlOOH) with Anhydride-Cured Epoxy Resins

Understanding the interaction between boehmite and epoxy and the formation of their interphases with different mechanical and chemical structures is crucial to predict and optimize the properties of epoxy-boehmite nanocomposites. Probing the interfacial properties with atomic force microscopy (AFM)-based methods, especially particle-matrix long-range interactions, is challenging. This is due to size limitations of various analytical methods in resolving nanoparticles and their interphases, the overlap of interphases, and the effect of buried particles that prevent the accurate interphase property measurement. Here, we develop a layered model system in which the epoxy is cured in contact with a thin layer of hydrothermally synthesized boehmite. Different microscopy methods are employed to evaluate the interfacial properties. With intermodulation atomic force microscopy (ImAFM) and amplitude dependence force spectroscopy (ADFS), which contain information about stiffness, electrostatic, and van der Waals forces, a soft interphase was detected between the epoxy and boehmite. Surface potential maps obtained by scanning Kelvin probe microscopy (SKPM) revealed another interphase about one order of magnitude larger than the mechanical interphase. The AFM-infrared spectroscopy (AFM-IR) technique reveals that the soft interphase consists of unreacted curing agent. The long-range electrical interphase is attributed to the chemical alteration of the bulk epoxy and the formation of new absorption bands.DFG, 232311024, FOR 2021: Wirkprinzipien nanoskaliger Matrixadditive für den Faserverbundleichtba

Fluoride recovery in degradable fluorinated polyesters

We report a new class of degradable fluorinated polymers through the copolymerization of tetrafluorophthalic anhydride and propylene oxide or trifluoropropylene oxide which show up to 20 times quicker degradation than the non-fluorinated equivalents and allow for fluoride recovery

The effect of boehmite nanoparticles (γ‐AlOOH) on nanomechanical and thermomechanical properties correlated to crosslinking density of epoxy

We show that complex physical and chemical interactions between boehmite nanoparticles and epoxy drastically affect matrix properties, which in the future will provide tuning of material properties for further optimization in applications from automotive to aerospace. We utilize intermodulation atomic force microscopy (ImAFM) for probing local stiffness of both particles and polymer matrix. Stiff particles are expected to increase total stiffness of nanocomposites and the stiffness of polymer should remain unchanged. However, ImAFM revealed that stiffness of matrix in epoxy/boehmite nanocomposite is significantly higher than unfilled epoxy. The stiffening effect of the boehmite on epoxy also depends on the particle concentration. To understand the mechanism behind property alteration induced by boehmite nanoparticles, network architecture is investigated using dynamic mechanical thermal analysis (DMTA). It was revealed that although with 15 wt% boehmite nanoparticles the modulus at glassy state increases, crosslinking density of epoxy for this composition is drastically low.DFG, 232311024, FOR 2021: Wirkprinzipien nanoskaliger Matrixadditive für den Faserverbundleichtba

Bestimmung mechanischer Eigenschaften dünner Polymerfilme mittels AFM-Kraft-Abstands-Kurven

In der vorliegenden Arbeit wurden AFM-Kraft-Abstands-Kurven benutzt, um die mechanischen Eigenschaften dünner Polymerfilme verschiedener Schichtdicken (2 - 400 nm) auf einem sehr viel steiferen Substrat (mechanische Doppelschichten) zu untersuchen. Die mechanischen Eigenschaften einer solchen Probe setzen sich aus den mechanischen Eigenschaften der Bestandteile, d.h. Polymer und Substrat, zusammen. Der Beitrag der Bestandteile hängt von der Schichtdicke und von der Auflagekraft ab. Es wurden existierende Modelle für die Auswertung von an Doppelschichten gemessenen Deformationskurven überprüft und festgestellt, dass kein Modell befriedigende Ergebnisse erzielt. Dies zeigte die Notwendigkeit einer neuen semiempirischen Theorie zur Beschreibung der Deformationskurven von mechanischen Doppelschichten. In dieser Arbeit wird der hyperbolische Fit zu diesem Zweck eingeführt. Die Validität des hyperbolischen Fit wurde anhand von drei Experimenten gezeigt. Alle experimentellen Kurven konnten sehr gut durch den hyperbolischen Fit beschrieben werden. Die Elastizitätsmoduln der Bestandteile konnten in Übereinstimmung mit den Literaturwerten berechnet werden. Die Schichtdicken der Proben konnten in allen Fällen mit großer Exaktheit bestimmt werden. Es wurde zudem die Möglichkeit der Auswertung einzelner Kraft-Abstands-Kurven untersucht. Damit konnte die Schichtdicke der untersuchten Doppelschichten ortsaufgelöst im Submikrometerbereich bestimmt werden und ein verstecktes Substrat detektiert werden. Die Adhäsion an der Grenzfläche Polymer/Substrat hat einen fundamentalen Einfluss auf die mechanischen Eigenschaften der Doppelschicht, der qualitativ im letzten Teil der Doktorarbeit gezeigt werden konnte.In this thesis AFM-force-distance-curves were used to examine the mechanical properties of thin polymer films with a large range of filmthicknesses (2 - 400 nm) on a considerable stiffer substrate, forming a mechanical double-layer. The mechanical properties of such a sample are composed of the mechanical properties of its constituents, i.e. polymer and substrate. The contribution of each constituent depends on the filmthickness and applied load. First, existing semi empirical models for the analysis of deformation curves on mechanical double-layers were examined. None of these models yielded satisfying results. This showed the need for a novel semi empirical model, describing deformation curves on mechanical double-layers. To this aim the hyperbolic fit is introduced. The validity of the hyperbolic fit was shown in three different experiments. All experimental curves could be described by the fit. The Fit parameters yielded the Young's modulus of the constituents in agreement with literature values and the filmthickness with great accuracy. Additionally, the analysis of single force-distance-curves was carried out. In this way an, in submicron-range, space-resolved reconstruction of the filmthickness could be achieved and a hidden substrate could be detected. The adhesion at the interface polymer/substrate has a fundamental influence on the mechanical properties of the Double-layer, which could be evaluated qualitatively in the last part of this thesis

Thioanhydride/isothiocyanate/epoxide ring-opening terpolymerisation: sequence selective enchainment of monomer mixtures and switchable catalysis

We report a new sequence selective terpolymerisation in which three monomers (butylene oxide (BO) A, PhNCS B and phtalic thioanhydride (PTA) C) are selectively enchained into an (ABA′C)n sequence. PTA/PhNCS/BO ring-opening terpolymerisation ROTERP can be coupled with CS2 ROTERP to generate tetrapolymers and with εDL ROP in switchable catalysis for blockpolymer synthesis

Long-Time Behavior of Surface Properties of Microstructures Fabricated by Multiphoton Lithography

The multiphoton lithography (MPL) technique represents the future of 3D microprinting, enabling the production of complex microscale objects with high precision. Although the MPL fabrication parameters are widely evaluated and discussed, not much attention has been given to the microscopic properties of 3D objects with respect to their surface properties and time-dependent stability. These properties are of crucial importance when it comes to the safe and durable use of these structures in biomedical applications. In this work, we investigate the surface properties of the MPL-produced SZ2080 polymeric microstructures with regard to the physical aging processes during the post-production stage. The influence of aging on the polymeric microstructures was investigated by means of Atomic Force Microscopy (AFM) and X-ray Photoelectron Spectroscopy (XPS). As a result, a time-dependent change in Young’s Modulus, plastic deformation, and adhesion and their correlation to the development in chemical composition of the surface of MPL-microstructures are evaluated. The results presented here are valuable for the application of MPL-fabricated 3D objects in general, but especially in medical technology as they give detailed information of the physical and chemical time-dependent dynamic behavior of MPL-printed surfaces and thus their suitability and performance in biological systems

Insights into Nano-Scale Physical and Mechanical Properties of Epoxy/Boehmite Nanocomposite Using Different AFM Modes

Understanding the interaction between nanoparticles and the matrix and the properties of interphase is crucial to predict the macroscopic properties of a nanocomposite system. Here, we investigate the interaction between boehmite nanoparticles (BNPs) and epoxy using different atomic force microscopy (AFM) approaches. We demonstrate benefits of using multifrequency intermodulation AFM (ImAFM) to obtain information about conservative, dissipative and van der Waals tip-surface forces and probing local properties of nanoparticles, matrix and the interphase. We utilize scanning kelvin probe microscopy (SKPM) to probe surface potential as a tool to visualize material contrast with a physical parameter, which is independent from the mechanics of the surface. Combining the information from ImAFM stiffness and SKPM surface potential results in a precise characterization of interfacial region, demonstrating that the interphase is softer than epoxy and boehmite nanoparticles. Further, we investigated the effect of boehmite nanoparticles on the bulk properties of epoxy matrix. ImAFM stiffness maps revealed the significant stiffening effect of boehmite nanoparticles on anhydride-cured epoxy matrix. The energy dissipation of epoxy matrix locally measured by ImAFM shows a considerable increase compared to that of neat epoxy. These measurements suggest a substantial alteration of epoxy structure induced by the presence of boehmite