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Computational Chemistry-Guided Syntheses and Crystal Structures of the Heavier Lanthanide Hydride Oxides DyHO, ErHO, and LuHOZapp, Nicolas, Sheptyakov, Denis, Kohlmann, Holger 03 May 2023 (has links)
Heteroanionic hydrides offer great possibilities in the design of functional materials. For ternary rare earth hydride oxide REHO, several modifications were reported with indications for a significant phase width with respect to H and O of the cubic representatives. We obtained DyHO and ErHO as well as the thus far elusive LuHO from solid-state reactions of RE2O3 and REH3 or LuH3 with CaO and investigated their crystal structures by neutron and X-ray powder diffraction. While DyHO, ErHO, and LuHO adopted the cubic anion-ordered half-Heusler LiAlSi structure type (F4¯3m, a(DyHO) = 5.30945(10) Å, a(ErHO) = 5.24615(7) Å, a(LuHO) = 5.171591(13) Å), LuHO additionally formed the orthorhombic anti-LiMgN structure type (Pnma; LuHO: a = 7.3493(7) Å, b = 3.6747(4) Å, c = 5.1985(3) Å; LuDO: a = 7.3116(16) Å, b = 3.6492(8) Å, c = 5.2021(7) Å). A comparison of the cubic compounds’ lattice parameters enabled a significant distinction between REHO and REH1+2xO1−x (x < 0 or x > 0). Furthermore, a computational chemistry study revealed the formation of REHO compounds of the smallest rare earth elements to be disfavored in comparison to the sesquioxides, which is why they may only be obtained by mild synthesis conditions.
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Turning on Fluorescence in Silico: From Radical Cations to 11-cis Locked Rhodopsin AnaloguesLaricheva, Elena N. 16 July 2012 (has links)
No description available.
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Polyphenols: Interactions with proteins and analytical methodsTrombley, John D. 05 December 2011 (has links)
No description available.
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A Multi-Scale Simulation Approach to Deformation Mechanism Prediction in SuperalloysLv, Duchao 21 December 2016 (has links)
No description available.
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Approximating Many-Body Induction to Efficiently Describe Molecular Liquids and Clusters With Improved AccuracyJacobson, Leif David 26 September 2011 (has links)
No description available.
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Properties of Liquid Water and Solvated Ions Based on First Principles CalculationsZheng, Lixin January 2018 (has links)
Water is of essential importance for life on earth, yet the physics concerning its various anomalous properties has not been fully illuminated. This thesis is dedicated to the understanding of liquid water from aspects of microscopic structures, dynamics, electronic structures, X-ray absorption spectra, and proton transfer mechanism. This thesis use the computational simulation techniques including density functional theory (DFT), ab initio molecular dynamics (AIMD), and theoretical models for X-ray absorption spectra (XAS) to investigate the dynamics and electronic structures of liquid water system. The topics investigated in this thesis include a comprehensive evaluation on the simulation of liquid water using the newly developed SCAN meta-GGA functional, a systematic modeling of the liquid-water XAS using advanced ab initio approaches, and an explanation for a long-puzzling question that why hydronium diffuses faster than hydroxide in liquid water. Overall, significant contributions have been made to the understanding of liquid water and ionic solutions in the microscopic level through the aid of ab initio computational modeling. / Physics
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Reduction of Copper Oxide by Formic Acid / Eine ab-initio Studie zur Kupferoxid-Reduktion durch AmeisensäureSchmeißer, Martin 24 November 2011 (has links) (PDF)
Four cluster models for a copper(I)oxide (111) surface have been designed, of which three were studied with respect to their applicability in density functional calculations in the general gradient approximation. Formic acid adsorption on these systems was modelled and yielded four different adsorption structures, of which two were found to have a high adsorption energy. The energetically most favourable adsorption structure was further investigated with respect to its decomposition and a few reactions with adsorbed H and OH species using synchronous transit methods to estimate reaction barriers and single point energy calculations for the reaction energy.
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From Interstellar Medium to Nanosurfaces: A Theoretical Study of Electronic Structure and Spectroscopic Properties of Molecules and ClustersPouladsaz, Davoud 22 September 2011 (has links)
This work tries to show the significant competence and functionality of density functional theory (DFT) and time-dependent density functional theory (TD-DFT) as theoretical approaches, supporting experimental measurements in various fields of physics from astrophysics to surface science, to study the electronic structure and spectroscopic properties of molecules and clusters:
Silicon nanocrystals: Due to their optical properties, silicon nanocrystals have attracted considerable attention in astrophysics. In this work, the optical properties of H-passivated silicon nanocrystals are determined by the energetics of the frontier orbitals and their dependence on the deformation in the relaxed excited state, using DFT and TD-DFT. The Jahn-Teller effect in the lowest excited state results in a distortion toward tetragonal symmetry, contributing significantly to the red shift of the photoluminescence (PL) spectra. Therefore, the deformation in the relaxed excited state consists of a symmetry conserving part and of a symmetry-breaking distortion from Td toward D2d. For nanocrystals up to a diameter of 1.5 nm, we project the deformations at the minima of the excited state potential surface onto the different symmetries, allowing for a discrimination of the respective contributions to the total Stokes shift. The results show a quantitative agreement between the TD-DFT calculations of PL gap and the observed PL energies better than 0.2 eV. It is also seen that the large PL linewidth is the fundamental property of each cluster, not of ensemble average over clusters of different size.
2,3-Benzofluorene: We have presented new theoretical results on the absorption spectroscopy of 2,3-benzofluorene (Bzf) for the transition from the ground state, S0, to the first electronically excited singlet state, S1, to support the measurements of S1(1A´) <- S0(1A´) absorption spectrum of jet-cooled Bzf. The potential energy surfaces (PESs) of the S(n=0,1,2) states of Bzf have been investigated with calculations based on DFT and TD-DFT. At the B3LYP/TZ level of theory, TD-DFT does not deliver a realistic difference between the excited S1 and S2 potential energy surfaces, a problem which can be avoided by introducing a reference geometry (q*) where this difference coincides with the observation. In this geometry, an expression for the Herzberg-Teller corrected intensities of the vibronic bands is proposed, allowing a straightforward assignment of the observed a′ modes below 900 cm−1, including realistic calculated intensities. In spite of the difficulties caused by the small energy difference between the S1 and S2 states, we have obtained a reasonable theoretical absorption spectrum based on a TD-DFT approach applied to the slightly modified molecular geometry. Although the agreement between the theoretical and observed spectra is very good only for vibrational modes with frequencies lower than 900 cm−1, we consider our calculations to be the best approach to an ab initio study realized for Bzf until now since only parametrized force fields had been used before.
(Ni–, Pd–, Pt–) Phthalocyanine: We studied the HOMO–LUMO gap shrinking in order to investigate the tip-induced polarization in scanning tunneling spectroscopy (STS) of d8 (Ni, Pd, and Pt) phthalocyanines. By means of DFT, the electronic structure and vibronic properties of single neutral NiPc, PdPc, and PtPc and their singly and doubly ionized cations and anions have been calculated. Interestingly, the position of the HOMO decreases systematically with increasing the atomic number of the central metal atom. The first ionization energies of neutral molecules increase by changing the central metal atom, while the electron affinities remain constant. This causes an increase in the HOMO–LUMO gap. These results show a clear correlation to experimental observations. Furthermore, partitioning of the reorganization energy, corresponding to the photoelectron spectra of the first and second ionizations of studied molecules, into normal mode contributions shows that the major contributions are due to several vibrational modes with a1g symmetry and energies lower than 1600 cm−1. The results reveal that the reorganization energy due to the singly positive ionization in the studied molecules is about one order of magnitude less than other reorganization energies, which makes these metal–phthalocyanines more attractive as electron donor for intramolecular electron transfer in electron acceptor–donor systems.
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Reduction of Copper Oxide by Formic Acid: an ab-initio studySchmeißer, Martin 29 September 2011 (has links)
Four cluster models for a copper(I)oxide (111) surface have been designed, of which three were studied with respect to their applicability in density functional calculations in the general gradient approximation. Formic acid adsorption on these systems was modelled and yielded four different adsorption structures, of which two were found to have a high adsorption energy. The energetically most favourable adsorption structure was further investigated with respect to its decomposition and a few reactions with adsorbed H and OH species using synchronous transit methods to estimate reaction barriers and single point energy calculations for the reaction energy.:1 Introduction
1.1 Preliminary Work
1.2 Known Reactions and Issues
1.3 Overview of Reactions and Species involved in Formic Acid Decomposition
2 Theoretical Background
2.1 The Schrödinger-Equation
2.2 Density Functional Theory
2.3 Exchange-Correlation Functionals
2.4 The Self-Consistent-Field Procedure
2.5 Geometry Optimization and Transition State Searches
2.6 Kinetics
3 Computational Details
3.1 Synchronous Transit Schemes
3.2 Transition State Searches using Eigenvector Following
4 Model System
5 Results and Discussion
5.1 Geometry of the Cu2O cluster structures
5.2 Adsorption of formic acid
5.3 Decomposition and Reaction Paths
5.3.1 Vibrational Analysis of the adsorbed Formic Acid Molecule
5.3.2 Reaction Modelling using Linear Synchronous Transit
5.3.3 Transition State Searches using Eigenvector Following
6 Summary and Outlook
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Untersuchungen von metallbesetzten Kohlenstoffnanoröhrchen für Sensoren und Interconnectsysteme mit ab-initio MethodenFuchs, Florian 13 March 2013 (has links)
Kohlenstoffnanoröhrchen (engl. carbon nanotubes, CNTs) sind Dank ihrer außergewöhnlichen elektrischen Eigenschaften Kandidaten für eine Vielzahl von Anwendungen im Bereich der Mikroelektronik. Ihre ballistischen Transporteigenschaften und die geringe Anfälligkeit auf Elektromigration sind vorteilhaft für die Anwendung von CNTs in Interconnectsystemen. Die Abhängigkeit der elektrischen Transporteigenschaften von mechanischer Verformung bildet weiterhin die Grundlage für die Produktion neuartiger Sensoren auf CNT-Basis. Durch die Besetzung mit Adatomen können diese Eigenschaften dabei weiter verbessert und bei der Herstellung gezielt eingestellt werden.
Die Verformung besetzter CNTs ist dabei ein noch relativ unerforschtes Gebiet. In dieser Arbeit wird dieses Verhalten untersucht. Zu Beginn wird gezeigt, dass die Eigenschaften von CNTs durch die Besetzung mit verschiedenen Metallen auf unterschiedliche Weise beeinflusst werden können. Dazu gehören auch Unterschiede zwischen den Spinzuständen, welche bei einigen der untersuchten Metalle auftreten. Durch die axiale Verformung der CNTs wird abschließend gezeigt, dass die Sensoreigenschaften von CNTs auch nach der Besetzung mit Metallen erhalten bleiben.:Zusammenfassung
1. Einleitung
2. Übersicht über Kohlenstoffnanoröhrchen
2.1. Geometrische Eigenschaften
2.1.1. Kohlenstoff als Grundbaustein für Graphen und CNTs
2.1.2. Geometrie von CNTs ausgehend von Graphen
2.2. Elektrische Struktur von Graphen und CNTs
2.3. Piezoelektrisches Verhalten
3. Theoretische Grundlagen
3.1. Dichtefunktionaltheorie
3.1.1. Grundproblem und Motivation
3.1.2. Grundstein der DFT - das Hohenberg-Kohn-Theorem
3.1.3. Praktische Umsetzung - die Kohn-Sham-Gleichungen
3.1.4. Abschätzung des Austausch-Korrelations-Funktionals
3.2. Grundlagen zum elektrischen Transport
3.2.1. Kurze Einführung zu Transportrechnungen
3.2.2. Landauer-Büttiker-Formalismus
4. Numerische Methoden
4.1. Initialisierung und Manipulation der Strukturen
4.2. Umsetzung der DFT
5. Berechnungen und Ergebnisse
5.1. Wahl des Modellsystems
5.1.1. Das zu untersuchende CNT
5.1.2. Auswahl der Adatome
5.2. Wahl der Parameter
5.3. Einige Überlegungen zum unbesetzten (8,4)-CNT
5.4. Untersuchung der Gleichgewichtspositionen
5.5. Analyse der Bandstruktur des besetzten CNTs
5.6. Einfluss auf Leitfähigkeit und Widerstand
5.7. Untersuchung der Spineigenschaften
5.8. Besetzungsgrad von Pd
5.9. Verformung der funktionalisierten CNTs
5.9.1. Implementation
5.9.2. Veränderungen der Struktur
5.9.3. Verhalten der Bandlücke bei einfacher Besetzung
5.9.4. Verhalten der Bandlücke bei mehrfacher Besetzung
5.9.5. Vergleich der verschieden besetzten CNTs bei Streckung
5.9.6. Verhalten des elektrischen Widerstandes bei Streckung
6. Zusammenfassung der Ergebnisse und Ausblick
Literaturverzeichnis
A. Bandstrukturen bei Verformung
B. Transmissionsfunktionen für Besetzungsgrade
C. Danksagung
D. Selbstständigkeitserklärung
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