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1. Thermomechanical properties of zero thermal expansion materials from theory and experiments

Author

Erlebach, Andreas, Thieme, Christian, Müller, Carolin, Hoffmann, Stefan, Höche, Thomas, Rüssel, Christian, and Sierka, Marek

Subjects
Condensed Matter - Materials Science
Abstract

Origin and composition dependence of the anisotropic thermomechanical properties are elucidated for Ba1-xSrxZn2Si2O7 (BZS) solid solutions. The high-temperature phase of BZS shows negative thermal expansion (NTE) along one crystallographic axis and highly anisotropic elastic properties characterized by X-ray diffraction experiments and simulations at the density functional theory level. Ab initio molecular dynamics simulations provide accurate predictions of the anisotropic thermal expansion in excellent agreement with experimental observations. The NTE considerably decreases with increasing Sr content x. This is connected with the composition dependence of the vibrational density of states (VDOS) and the anisotropic Gr\"uneisen parameters. The VDOS shifts to higher frequencies between 0-5 THz due to substitution of Ba with Sr. In the same frequency range, vibrational modes contributing most to the NTE are found. In addition, phonon calculations using the quasi-harmonic approximation revealed that the NTE is mainly connected with deformation of four-membered rings formed by SiO4 and ZnO4 tetrahedra. The thermomechanical and vibrational properties obtained in this work provide the basis for future studies facilitating the targeted design of BZS solid solutions as zero or negative thermal expansion material.

Published
2024
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2. Phase stability determination of negative thermal expansion silicates by theory and experiment

Author

Erlebach, Andreas, Hassine, Ghada Belhadj, Thieme, Christian, Thieme, Katrin, Rüssel, Christian, and Sierka, Marek

Subjects
Condensed Matter - Materials Science
Abstract

Materials that exhibit zero thermal expansion have numerous applications, ranging from everyday ceramic hobs to telescope mirrors to devices in optics and micromechanics. These materials include glass ceramics containing crystal phases with negative thermal expansion in at least one crystallographic direction, such as Ba1-xSrxZn2-2yMg2ySi2O7 solid solutions. However, the volume increase associated with the martensitic phase transformation in these crystals often hinders their use as zero thermal expansion materials at operating temperatures near the transition temperature Tt. Here, an approach to rapidly predict Tt of such materials as a function of chemical composition based on a combination of density functional theory simulations and experiments has been developed and applied to Ba1-xSrxZn2-2yMg2ySi2O7. Its central element is the modeling of free energy as a function of temperature and chemical composition using a composition-dependent Debye model augmented by an empirical correction, which incorporates the effects of anharmonic lattice vibrations. This approach provides Tt predictions with an estimated uncertainty of about 100 K, which is similar to the accuracy of computationally much more demanding simulations of polymorphous phase transitions. In addition, this approach allows computationally efficient determination of the chemical compositions at which the Ba1-xSrxZn2-2yMg2ySi2O7 phase with the desired thermal properties will be formed during synthesis, facilitating the targeted design of zero thermal expansion materials.

Published
2024
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3. Structure and crystallization of SiO2 and B2O3 doped lithium disilicate glasses from theory and experiment

Author

Erlebach, Andreas, Thieme, Katrin, Sierka, Marek, and Rüssel, Christian

Subjects
Condensed Matter - Materials Science
Abstract

Solid solutions of SiO2 and B2O3 in Li2O 2SiO2 are synthesized and characterized for the first time. Their structure and crystallization mechanisms are investigated employing a combination of simulations at the density functional theory level and experiments on the crystallization of SiO2 and B2O3 doped lithium disilicate glasses. The remarkable agreement of calculated and experimentally determined cell parameters reveals the preferential, kinetically controlled incorporation of [SiO4] and [BO4] at the Li+ lattice sites of the Li2O 2SiO2 crystal structure. While the addition of SiO2 increases the glass viscosity resulting in lower crystal growth velocities, glasses containing B2O3 show a reduction of both viscosities and crystal growth velocities. These observations could be rationalized by a change of the chemical composition of the glass matrix surrounding the precipitated crystal phase during the course of crystallization, which leads to a deceleration of the attachment of building units required for further crystal growth at the liquid-crystal interface.

Published
2024
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4. Thermodynamic compatibility of actives encapsulated into PEG-PLA nanoparticles: In Silico predictions and experimental verification

Author

Erlebach, Andreas, Ott, Timm, Otzen, Christoph, Schubert, Stephanie, Czaplewska, Justyna, Schubert, Ulrich S., and Sierka, Marek

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Materials Science
Abstract

Achieving optimal solubility of active substances in polymeric carriers is of fundamental importance for a number of industrial applications, including targeted drug delivery within the growing field of nanomedicine. However, its experimental optimization using a trial-and-error approach is cumbersome and time-consuming. Here, an approach based on molecular dynamics (MD) simulations and the Flory-Huggins theory is proposed for rapid prediction of thermodynamic compatibility between active species and copolymers comprising hydrophilic and hydrophobic segments. In contrast to similar methods, our approach offers high computational efficiency by employing MD simulations that avoid explicit consideration of the actual copolymer chains. The accuracy of the method is demonstrated for compatibility predictions between pyrene and nile red as model dyes as well as indomethacin as model drug and copolymers containing blocks of poly(ethylene glycol) and poly(lactic acid) in different ratios. The results of the simulations are directly verified by comparison with the observed encapsulation efficiency of nanoparticles prepared by nanoprecipitation.

Published
2024
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5. Structure evolution of nanoparticulate Fe2O3

Author

Erlebach, Andreas, Kurland, Heinz-Dieter, Grabow, Janet, Müller, Frank A., and Sierka, Marek

Subjects
Condensed Matter - Materials Science
Abstract

The atomic structure and properties of nanoparticulate Fe2O3 are characterized starting from its smallest Fe2O3 building unit through (Fe2O3)n clusters to nanometer-sized Fe2O3 particles. This is achieved by combining global structure optimizations at the density functional theory level, molecular dynamics simulations by employing tailored, ab initio parameterized interatomic potential functions and experiments. With the exception of nearly tetrahedral, adamantane-like (Fe2O3)2 small (Fe2O3)n clusters assume compact, virtually amorphous structures with little or no symmetry. For n = 2-5 (Fe2O3)n clusters consist mainly of two- and three-membered Fe-O rings. Starting from n = 5 they increasingly assume tetrahedral shape with the adamantane-like (Fe2O3)2 unit as the main building block. However, the small energy differences between different isomers of the same cluster-size make precise structural assignment for larger (Fe2O3)n clusters difficult. The tetrahedral morphology persists for Fe2O3 nanoparticles with up to 3 nm in diameter. Simulated crystallization of larger nanoparticles with diameters of about 5 nm demonstrates pronounced melting point depression and leads to formation of {\epsilon}-Fe2O3 single crystals with hexagonal morphology. This finding is in excellent agreement with the results obtained for Fe2O3 nanopowders generated by laser vaporization and provides the first direct indication that {\epsilon}-Fe2O3 may be thermodynamically the most stable phase in this size regime.

Published
2024
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6. Structure and magnetic properties of (Fe2O3)n clusters (n = 1-5)

Author

Erlebach, Andreas, Hühn, Carolin, Jana, Richard, and Sierka, Marek

Subjects
Condensed Matter - Materials Science
Abstract

Global minimum structures of neutral (Fe2O3)n clusters with n = 1-5 were determined employing the genetic algorithm in combination with ab initio parameterized interatomic potentials and subsequent refinement at the density functional theory level. Systematic investigations of magnetic configurations of the clusters using a broken symmetry approach reveal antiferromagnetic and ferrimagnetic ground states. Whereas (Fe2O3)n clusters with n = 2-5 contain exclusively Fe3+, Fe2O3 was found to be a special case formally containing both Fe2+ and Fe3+. Calculated magnetic coupling constants revealed predominantly strong antiferromagnetic interactions, which exceed bulk values found in hematite. The precise magnetization (spin) state of the clusters has only small influence on their geometric structure. Starting from n = 4 also the relative energies of different cluster isomers are only weakly influenced by their magnetic configuration. These findings are important for simulations of larger (Fe2O3)n clusters and nanoparticles.

Published
2024
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8. A reactive neural network framework for water-loaded acidic zeolites

Author

Erlebach, Andreas, Šípka, Martin, Saha, Indranil, Nachtigall, Petr, Heard, Christopher J., and Grajciar, Lukáš

Subjects
Condensed Matter - Materials Science
Abstract

Under operating conditions, the dynamics of water and ions confined within protonic aluminosilicate zeolite micropores are responsible for many of their properties, including hydrothermal stability, acidity and catalytic activity. However, due to high computational cost, operando studies of acidic zeolites are currently rare and limited to specific cases and simplified models. In this work, we have developed a general reactive neural network potential (NNP) attempting to cover the entire class of acidic zeolites, including the full range of experimentally relevant water concentrations and Si/Al ratios. This NNP combines dramatic sampling acceleration, retaining the reference metaGGA DFT level, with the capacity for discovery of new chemistry, such as collective defect formation mechanisms at the zeolite surface. Furthermore, we exemplify how the NNP can be used as a basis for further extensions/improvements which include data-efficient adoption of higher-level (hybrid) references via $\Delta$-learning and the acceleration of rare event sampling via automatic construction of collective variables. These developments represent a significant step towards accurate simulations of realistic catalysts under operando conditions., Comment: Revised manuscript and supplementary information

Published
2023
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9. Understanding chemical reactions via variational autoencoder and atomic representations

Author

Šípka, Martin, Erlebach, Andreas, and Grajciar, Lukáš

Subjects
Physics - Chemical Physics
Abstract

On the time scales accessible to atomistic numerical modelling, chemical reactions are considered rare events. Atomistic simulations are typically biased along a low-dimensional representation of a chemical reaction in an atomic structure space, i.e., along the collective variable, to accelerate sampling of these improbable events. However, suitable collective variables are often complicated to guess due to the complexity of the transitions. Therefore, we present an automatic method of generating robust collective variables from atomic representation vectors, using either fixed Behler-Parrinello functions or representations extracted from pre-trained machine learning potentials. Variational autoencoder with these representations as inputs is trained while its latent space with arbitrary dimension gives us the set of collective variables. The resulting collective variables inherit all necessary invariances from the atomic representations and can be trained entirely unsupervised. The method's effectiveness is demonstrated using three different chemical reactions, one being the complex hydrolysis of a heterogeneous aluminosilicate catalyst. Lastly, we consider the method in the context of unseen atomic structure prediction, efficiently creating structures for different values of collective variables in a generative model fashion.

Published
2022

10. Accurate large-scale simulations of siliceous zeolites by neural network potentials

Author

Erlebach, Andreas, Nachtigall, Petr, and Grajciar, Lukáš

Subjects
Condensed Matter - Materials Science
Abstract

The computational discovery and design of zeolites is a crucial part of the chemical industry. Finding highly accurate while computationally feasible protocol for identification of hypothetical zeolites that could be targeted experimentally is a great challenge. To tackle the challenge, we trained neural network potentials (NNP) with the SchNet architecture on a structurally diverse database of density functional theory (DFT) data. This database was iteratively extended by active learning to cover not only low-energy equilibrium configurations but also high-energy transition states. We demonstrate that the resulting reactive NNPs retain the accuracy of the DFT reference for thermodynamic stabilities, vibrational properties, and reactive and non-reactive phase transformations. The novel NNPs outperforms specialized, analytical force fields for silica, such as ReaxFF, by order(s) of magnitude in accuracy, while speeding up the calculations in comparison to DFT by at least three orders of magnitude. As a showcase, we screened an existing zeolite database containing 330 thousand structures and revealed more than 20 thousand additional hypothetical frameworks in the thermodynamically accessible range of zeolite synthesis. Hence, our NNPs are expected to be essential for future high-throughput studies on the structure and reactivity of hypothetical and existing zeolites., Comment: This version of the article has been accepted for publication, after peer review (when applicable) but is not the Version of Record and does not reflect post-acceptance improvements, or any corrections. The Version of Record is available on line at: http://dx.doi.org/10.1038/s41524-022-00865-w

Published
2021
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22. Understanding chemical reactions via variational autoencoder and atomic representations

Author

����pka, Martin, Erlebach, Andreas, and Grajciar, Luk����

Subjects
Chemical Physics (physics.chem-ph), FOS: Physical sciences
Abstract

On the time scales accessible to atomistic numerical modelling, chemical reactions are considered rare events. Atomistic simulations are typically biased along a low-dimensional representation of a chemical reaction in an atomic structure space, i.e., along the collective variable, to accelerate sampling of these improbable events. However, suitable collective variables are often complicated to guess due to the complexity of the transitions. Therefore, we present an automatic method of generating robust collective variables from atomic representation vectors, using either fixed Behler-Parrinello functions or representations extracted from pre-trained machine learning potentials. Variational autoencoder with these representations as inputs is trained while its latent space with arbitrary dimension gives us the set of collective variables. The resulting collective variables inherit all necessary invariances from the atomic representations and can be trained entirely unsupervised. The method's effectiveness is demonstrated using three different chemical reactions, one being the complex hydrolysis of a heterogeneous aluminosilicate catalyst. Lastly, we consider the method in the context of unseen atomic structure prediction, efficiently creating structures for different values of collective variables in a generative model fashion.

Published
2022
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29. Methods for in silico design of innovative materials

Author

Erlebach, Andreas

Abstract

Time and cost efficient optimization of existing and design of novel materials is achieved by prediction of the materials structure and properties by employing computational - in silico - methods. First, predictions of the phase stability and thermomechanical properties for zero thermal expansion glass ceramics consisting of Ba1-mSrmZn2-2nMg2nSi2O7 (BZS) solid solutions. Predictions of the martensitic phase transition temperature show good agreement with experimental observations. Moreover, the origin of the negative thermal expansion at the atomic level was revealed for Ba0.5Sr0.5Zn2Si2O7 by using density functional theory simulations. The second case study was the elucidation of the atomic structure and crystallization of nanoparticulate Fe2O3 starting from its smallest Fe2O3 building block up to nanometer-sized Fe2O3 particles. Most of the (Fe2O3)n clusters show compact, almost amorphous structures with little or no symmetry, except for the tetrahedral, adamantane-like (Fe2O3)2 structure. Simulated crystallization of larger nanoparticles with diameters of about 5 nm resulted in ϵ-Fe2O3 single crystals with hexagonal morphology. The hexagonal morphology is in excellent agreement with experimental results providing the first direct indication that ϵ-Fe_2O_3 may be thermodynamically the most stable phase for nanoparticles of this size. Finally, the third example case focusses on the optimization of polymeric nanocarriers for the efficient encapsulation of biologically active substances such as drugs. Therefore, the thermodynamic compatibility of polymers with low molecular weight compounds is evaluated using thermodynamic models parameterized by atomistic simulations. The physico-chemical properties of the investigated polymers show good agreement with experimental observations., Die zeit- und kosteneffiziente Optimierung existierender sowie das Designs neuer Materialien wurde durch die Vorhersage der Materialstruktur und -eigenschaften mithilfe rechengestützter - in silico - Methoden erzielt. Zum einen erfolgten Vorhersagen der Phasenstabilität und der thermomechanischen Eigenschaften von Glaskeramiken mit null Wärmeausdehnung bestehend aus Ba1-mSrmZn2-2nMg2nSi2O7 (BZS) Mischkristallen. Vorhersagen der martensitischen Phasenübergangstemperatur zeigen gute Übereinstimmung mit experimentellen Beobachtungen. Außerdem wurde der Ursprung der negativen thermischen Ausdehnung auf atomaren Niveau für Ba0.5Sr0.5Zn2Si2O7 mithilfe von Dichtefunktionaltheorie Simulationen aufgeklärt. Eine zweite Fallstudie betraf die Aufklärung der atomaren Struktur und Kristallisation von nanopartikulärem Fe2O3, beginnend mit dem kleinsten Fe2O3-Baustein bis zu nanometergroßen Fe2O3-Partikeln. Die meisten der (Fe2O3)n-Cluster zeigen kompakte, fast amorphe Strukturen mit geringer oder keiner Symmetrie mit Ausnahme der tetraedrischen, Adamantan-ähnlichen (Fe2O3)2 Struktur. Die simulierte Kristallisation größerer Nanopartikel mit Durchmessern von etwa 5 nm ergab ϵ-Fe2O3 Einkristalle mit hexagonaler Morphologie. Die hexagonale Morphologie stimmt hervorragend mit experimentellen Ergebnissen überein, was den ersten direkten Hinweis dafür liefert, dass ϵ-Fe2O3 die thermodynamisch stabilste Phase für Nanopartikel dieser Größe sein kann. Das dritte Fallbeispiel befasste sich mit der Optimierung von polymeren Nanopartikeln für die effiziente Einkapselung biologisch aktiver Substanzen. Hierfür wurde die thermodynamische Kompatibilität von Polymeren mit niedermolekularen Verbindungen mithilfe thermodynamischer Modelle errechnet, die durch atomistische Simulationen parametrisiert wurden. Die berechneten physikalisch-chemischen Eigenschaften der untersuchten Polymere zeigen gute Übereinstimmung mit experimentellen Beobachtungen.

Published
2019
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30. Kinetics of Decelerated Meltingorr

Author

Wondraczek, Lothar, Pan, Zhiwen, Palenta, Theresia, Erlebach, Andreas, Misture, Scott T., Sierka, Marek, Micoulaut, Matthieu, Hoppe, Uwe, Deubener, Joachim, and Greaves, G. Neville

Abstract

Advanced science 5(5), 1700850 (2018). doi:10.1002/advs.201700850, Melting presents one of the most prominent phenomena in condensed matter science. Its microscopic understanding, however, is still fragmented, ranging from simplistic theory to the observation of melting point depressions. Here, a multimethod experimental approach is combined with computational simulation to study the microscopic mechanism of melting between these two extremes. Crystalline structures are exploited in which melting occurs into a metastable liquid close to its glass transition temperature. The associated sluggish dynamics concur with real‐time observation of homogeneous melting. In‐depth information on the structural signature is obtained from various independent spectroscopic and scattering methods, revealing a step‐wise nature of the transition before reaching the liquid state. A kinetic model is derived in which the first reaction step is promoted by local instability events, and the second is driven by diffusive mobility. Computational simulation provides further confirmation for the sequential reaction steps and for the details of the associated structural dynamics. The successful quantitative modeling of the low‐temperature decelerated melting of zeolite crystals, reconciling homogeneous with heterogeneous processes, should serve as a platform for understanding the inherent instability of other zeolitic structures, as well as the prolific and more complex nanoporous metal–organic frameworks., Published by Wiley-VCH, Weinheim

Published
2018
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32. Kinetics of Decelerated Melting

Author

Wondraczek, Lothar, primary, Pan, Zhiwen, additional, Palenta, Theresia, additional, Erlebach, Andreas, additional, Misture, Scott T., additional, Sierka, Marek, additional, Micoulaut, Matthieu, additional, Hoppe, Uwe, additional, Deubener, Joachim, additional, and Greaves, G. Neville, additional

Published
2018
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42. WO3 as a nucleating agent for BaO/SrO/ZnO/SiO2 glasses – experiments and simulations.

Author

Thieme, Christian, Erlebach, Andreas, Patzig, Christian, Thieme, Katrin, Sierka, Marek, Höche, Thomas, and Rüssel, Christian

Subjects
*TUNGSTEN trioxide, *NUCLEATING agents, *THERMAL expansion, *CRYSTALLIZATION, *X-ray diffraction
Abstract

Recently, it has been shown that the Ba1−xSrxZn2Si2O7 crystal phase has a negative coefficient of thermal expansion. However, technological applications of this material as low thermal expansion glass ceramics are limited by the undesired surface crystallization of the corresponding glass. Surface nucleation, however, can be turned into bulk nucleation by adding nucleating agents. Here, glasses in the base system BaO–SrO–ZnO–SiO2 with small additions of ZrO2 and WO3 were synthesized and their crystallization behavior was investigated using thermal analysis, X-ray diffraction, electron microscopy, and density functional theory simulations. The addition of WO3 leads to the formation of volume crystals with a scheelite crystal structure (Ba1−xSrxWO4) in high number density. The limited incorporation of Si4+ ions into these crystals is discussed. Possible crystal lattice sites for Si4+ were located by density functional theory simulations. In a much lower number density, crystals with a crystal structure similar to the high-temperature polymorph of BaZn2Si2O7 and the Ba1−xSrxZn2Si2O7 composition crystallize as well. These crystals can reach a larger size than the scheelite crystals that occur in parallel. The overall microstructure is thus formed by small dendritic crystals with a scheelite structure and huge Ba1−xSrxZn2Si2O7 crystals. Both of them seem to grow independently of each other. In spite of the high anisotropy of both phases, the microstructure is revealed to be free of cracks. [ABSTRACT FROM AUTHOR]

Published
2018
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44. Structure and crystallization of SiO2 and B2O3 doped lithium disilicate glasses from theory and experiment.

Author

Erlebach, Andreas, Thieme, Katrin, Sierka, Marek, and Rüssel, Christian

Abstract

Solid solutions of SiO2 and B2O3 in Li2O·2SiO2 are synthesized and characterized for the first time. Their structure and crystallization mechanisms are investigated employing a combination of simulations at the density functional theory level and experiments on the crystallization of SiO2 and B2O3 doped lithium disilicate glasses. The remarkable agreement of calculated and experimentally determined cell parameters reveals the preferential, kinetically controlled incorporation of [SiO4] and [BO4] at the Li+ lattice sites of the Li2O·2SiO2 crystal structure. While the addition of SiO2 increases the glass viscosity resulting in lower crystal growth velocities, glasses containing B2O3 show a reduction of both viscosities and crystal growth velocities. These observations could be rationalized by a change of the chemical composition of the glass matrix surrounding the precipitated crystal phase during the course of crystallization, which leads to a deceleration of the attachment of building units required for further crystal growth at the liquid–crystal interface. [ABSTRACT FROM AUTHOR]

Published
2017
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45. Different Reactivity of As4 towards Disilenes and Silylenes.

Author

Seitz, Andreas E., Eckhardt, Maria, Sen, Sakya S., Erlebach, Andreas, Peresypkina, Eugenia V., Roesky, Herbert W., Sierka, Marek, and Scheer, Manfred

Subjects
NUCLEAR magnetic resonance spectroscopy, X-ray diffraction, ELECTROMAGNETIC wave diffraction, TRIMETHYLSILYL compounds, METHYLSILYL compounds
Abstract

The activation of yellow arsenic is possible with the silylene [PhC(NtBu)2SiN(SiMe3)2] ( 1) and the disilene [(Me3Si)2N(η1-Me5C5)Si=Si(η1-Me5C5)N(SiMe3)2] ( 3). The reaction of As4 with 1 leads to the unprecedented As10 cage compound [(LSiN(SiMe3)2)3As10] ( 2; L=PhC(NtBu)2) with an As7 nortricyclane core stabilized by arsasilene moieties containing silicon(II)bis(trimethylsilyl)amide substituents. In contrast, the compound [Cp*{(SiMe3)2N}SiAs]2 ( 4) containing a butterfly-like diarsadisilabicyclo[1.1.0]butane unit is formed by the reaction of As4 with the disilene 3. Both compounds were characterized by single-crystal X-ray diffraction analysis, NMR spectroscopy, and mass spectrometry. The reaction outcomes demonstrate the different reaction behavior of yellow arsenic (As4) compared to white phosphorus (P4) in the reactions with the corresponding silylenes and disilenes. [ABSTRACT FROM AUTHOR]

Published
2017
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46. Unterschiedliche Reaktivität von As4 gegenüber Disilenen und Silylenen.

Author

Seitz, Andreas E., Eckhardt, Maria, Sen, Sakya S., Erlebach, Andreas, Peresypkina, Eugenia V., Roesky, Herbert W., Sierka, Marek, and Scheer, Manfred

Abstract

Copyright of Angewandte Chemie is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2017
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47. Thermodynamic compatibility of actives encapsulated into PEG-PLA nanoparticles: In Silico predictions and experimental verification.

Author

Erlebach, Andreas, Ott, Timm, Otzen, Christoph, Schubert, Stephanie, Czaplewska, Justyna, Schubert, Ulrich S., and Sierka, Marek

Subjects
*ENCAPSULATION (Catalysis), *BLOCK copolymers, *MOLECULAR dynamics, *DRUG carriers, *FLORY-Huggins theory, *PRECIPITATION (Chemistry)
Abstract

Achieving optimal solubility of active substances in polymeric carriers is of fundamental importance for a number of industrial applications, including targeted drug delivery within the growing field of nanomedicine. However, its experimental optimization using a trial-and-error approach is cumbersome and time-consuming. Here, an approach based on molecular dynamics (MD) simulations and the Flory-Huggins theory is proposed for rapid prediction of thermodynamic compatibility between active species and copolymers comprising hydrophilic and hydrophobic segments. In contrast to similar methods, our approach offers high computational efficiency by employing MD simulations that avoid explicit consideration of the actual copolymer chains. The accuracy of the method is demonstrated for compatibility predictions between pyrene and nile red as model dyes as well as indomethacin as model drug and copolymers containing blocks of poly(ethylene glycol) and poly(lactic acid) in different ratios. The results of the simulations are directly verified by comparison with the observed encapsulation efficiency of nanoparticles prepared by nanoprecipitation. © 2016 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published
2016
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49. The Structure of Gd 3+ -Doped Li 2 O and K 2 O Containing Aluminosilicate Glasses from Molecular Dynamics Simulations.

Author

Zekri, Mohamed, Herrmann, Andreas, Erlebach, Andreas, Damak, Kamel, Rüssel, Christian, Sierka, Marek, and Maâlej, Ramzi

Subjects
MOLECULAR dynamics, GLASS transition temperature, GADOLINIUM, ATOMIC structure, GLASS structure, POLYMER networks
Abstract

Understanding the atomic structure of glasses is critical for developing new generations of materials with important technical applications. In particular, the local environment of rare-earth ions and their distribution and clustering is of great relevance for applications of rare earth-containing glasses in photonic devices. In this work, the structure of Gd2O3 doped lithium and potassium aluminosilicate glasses is investigated as a function of their network modifier oxide (NMO–Li2O, K2O) to aluminum oxide ratio using molecular dynamics simulations. The applied simulation procedure yields a set of configurations, the so-called inherent structures, of the liquid state slightly above the glass transition temperature. The generation of a large set of inherent structures allows a statistical sampling of the medium-range order of the Gd3+ ions with less computational effort compared to other simulation methods. The resulting medium-range atomic structures of network former and modifier ions are in good agreement with experimental results and simulations of similar glasses. It was found that increasing NMO/Al ratio increases the network modifier coordination number with non-bridging oxygen sites and reduces the overall stability of the network structure. The fraction of non-bridging oxygen sites in the vicinity of Gd3+ ions increases considerably with decreasing field strength and increasing concentration of the network modifier ions. These correlations could be confirmed even if the simulation results of alkaline earth aluminosilicate glasses are added to the analysis. In addition, the structure predictions generally indicate a low driving force for the clustering of Gd3+. Here, network modifier ions of large ionic radii reduce the probability of Gd–O–Gd contacts. [ABSTRACT FROM AUTHOR]

Published
2021
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