Beiträge zur Darstellung binärer und ternärer Nitride der Elemente Ga, Ru, Rh, Pd, Au, U

Heckers, Uwe.

Unknown Date

Universiẗat, Diss., 2002--Dortmund.

Mineral i jordens inre : Hur kristallstrukturer förändras med tryck

Eklöf, Sara

January 2011

Jordens innandöme är uppdelat i flera olika delar, vilket beror på gravitationen och kemisk differentiering. Skillnaden i tryck, temperatur och kemi mellan jordens skorpa, mantel och kärna är en förklaring till varför mineral ändrar karaktär längre ner i jorden. Djupare ner i jorden ökar trycket, men också temperaturen. Ökat tryck gör att atomerna packas tätare, medan ökad temperatur å andra sidan gör att mineralen expanderar. Detta är en av anledningarna till varför det är så svårt att bestämma stabilitetsområden för mineral, det vill säga vid vilka tryck och temperaturer de är stabila. En annan anledning till att det är svårt att ta reda på hur det ser ut inne i jorden är att man inte kan ta prov så väldigt djupt ner. Istället får man förlita sig på experimentella metoder som diamantcellen. Denna uppsats bygger på litteraturstudier av ett antal artiklar som behandlar högtrycksmineral. Syftet är att beskriva vilka mineral som finns i jordens inre, och hur dessa mineral förändras med ökat tryck. De mineral som tas upp är kvarts, olivin, granat, grafit och järn, och deras kristallstrukturer, högtryckspolymorfer och fasomvandlingar förklaras. Med ökat tryck går mineral oftast från komplicerade och relativt öppna strukturer till enklare och symmetriska tätpackade strukturer. Med detta följer en betydande minskning av volymen och därmed också en ökning av densiteten. Med ökat djup blir också ofta den kemiska sammansättningen enklare. / Sara Eklöf

mineral

högt tryck

högtrycksmineral

kvarts

olivin

granat

grafit

järn

kristallstruktur

högtryckspolymorf

fasomvandling

Earth and Related Environmental Sciences

Geovetenskap och miljövetenskap

Preparation and Characterization of Clathrates in the Systems Ba – Ge, Ba – Ni – Ge, and Ba – Ni – Si: Preparation and Characterization of Clathrates in the Systems Ba – Ge, Ba – Ni – Ge, and Ba – Ni – Si

Aydemir, Umut

04 June 2012

The main focus of this work is the preparation, chemical and structural characterization along with the investigation of physical properties of intermetallic clathrates. Starting from the history of clathrate research, classification of clathrate types, their structural properties and possible application areas are evaluated in chapter 2. The methodologies of sample preparation and materials characterization as well as quantum chemical calculations are discussed in chapter 3. The complete characterization of Ba8Ge433 ( is a Schottky-symbol standing for vacancies),12-14 which is a parent compound for the variety of ternary variants, is the subject of chapter 4. Ba8Ge433 is a high temperature phase,12 which was prepared for the first time as single phase bulk material in this work.15, 16 In this way, the intrinsic transport properties could be investigated without influence of grain boundary and impurity effects. The transport behavior is analyzed at low and high temperatures and referred to the former results. In addition, crystal structure and vacancy ordering in terms of the reaction conditions are discussed. Chemical bonding in Ba8Ge433 is investigated by topological analysis of the electron localizability indicator and the electron density. Chapter 5 deals with the preparation, phase analysis, crystal structure and physical properties of BaGe5, which constitutes a new clathrate type oP60.17, 18 So far, two clathrate types were known in the binary system Ba – Ge, namely the clathrate cP124 Ba6Ge25,19-21 and the clathrate-I Ba8Ge433. Originally, BaGe5 was detected by optical and scanning electron microscopy within the grains of Ba8Ge433.12 Once the preparation of phase-pure Ba8Ge433 was achieved, it became possible to make detailed investigations of its decomposition along with the formation of BaGe5. A detailed theoretical and experimental analysis on the relation between crystal structure and physical properties of BaGe5 is presented. In chapter 6, a thorough structural characterization and the physical properties of clathrates in the system Ba – Ni – Ge is presented based on the subtle relation between the crystal structure containing vacancies and the thermoelectric properties. During the investigations in this system, a large single crystal was grown by Nguyen et al. 22, 23 from the melt with the composition Ba8Ni3.5Ge42.10.4. A systematic reinvestigation of the phase relations in this system was performed and the influence of different Ni content to the crystal structure and physical properties is evaluated. The Si-based ternary clathrate with composition Ba8–δNixySi46–x–y is the subject of chapter 7. The phase relations and the homogeneity range are established. The crystal structure taking into account vacancies in the framework is discussed. Physical properties of bulk pieces are analyzed and the results are related to the sample composition. In addition, first-principles electronic structure calculations are carried out to assess variations in the electronic band structure, phase stability and chemical bonding.24 Chapter 8 reports on the intermetallic compound Ba3Si4,25, 26 which was encountered during the investigations on the Ba – Ni – Si phase diagram. The discussion covers issues related to preparation, crystal structure, phase diagram analysis, electrical and magnetic properties, NMR measurements, quantum mechanical calculations and oxidation to nanoporous silicon with gaseous HCl. Besides my contributions to the NoE CMA, I studied under the Priority Program 1178 of Deutsche Forschungsgemeinschaft “Experimental electron density as the key for understanding chemical interactions” with the project of “Charge distribution changes by external electric fields: investigations of bond selective redistributions of valence electron densities”. Chapter 9 deals with the preparation of chalcopyrites ZnSiP2 and CuAlS2 for experimental charge density analysis. Both phases show semiconducting properties and have non-centrosymmetric structures with high space group symmetry as needed to investigate the structural changes induced by external electric field. In this chapter, I describe the preparation and the crystal structure analyses of ZnSiP2 and CuAlS2 including issues related to the data collection as well as the results of NMR investigation.

info:eu-repo/classification/ddc/530

ddc:530

Zur Bildung von Hydrogencarbonaten mehrwertiger Metalle

Rincke, Christine

26 September 2018

In der Literatur finden sich nur sehr wenige Hinweise zu Darstellungsmöglichkeiten fester Hydrogencarbonate mehrwertiger Metallionen. Im Rahmen der Arbeit sollte diesen nachgegangen werden. Die Untersuchungen zu Ni(HCO3)2, Gd(HCO3)3∙5H2O, Ho(HCO3)3∙6H2O, Mg(HCO3)2, [Mg2(H2O)6(HCO3)3]Cl sowie CsMgH(CO3)2∙4H2O widerlegen allerdings deren Existenz unter den in der Literatur angegebenen Bedingungen. Stattdessen ist die Synthese von bisher unbekannten Carbonaten (Ni12(CO3)8(OH)6O∙(6-8)H2O, NiCO3∙5,5H2O, MgCO3∙6H2O, MgCO3∙MgCl2∙7H2O, Cs2Mg4(CO3)5∙10H2O), deren umfangreiche Charakterisierung sowie deren Kristallstrukturlösung gelungen. Weiterhin sollten ausgewählte Fragestellungen des reziproken Systems K⁺, Mg²⁺ // HCO₃⁻, Cl⁻ – H₂O bei 25°C und einem CO2-Druck von 1 bar untersucht werden. Es wurden Löslichkeitsversuche in den Existenzbereichen der Bodenkörper KMgH(CO3)2∙4H2O und MgCO3∙MgCl2∙7H2O durchgeführt, mit dem Ziel Literaturdaten zu verifizieren und Grundlagen für die Aufnahme dieser Phasen in thermodynamische Berechnungen zu schaffen.

info:eu-repo/classification/ddc/540

ddc:540

Hydrogencarbonate

Carbonate

Anorganische Salze

Kristallstruktur

Doppelsalze

(3,5-Di­methyl-1H-pyrazol-1-yl)tri­methyl­silane

Böhme, Uwe, Bitto, Florian

17 January 2022

The title compound, C8H16N2Si, crystallizes in the the ortho­rhom­bic space group P212121 with one mol­ecule in the asymmetric unit. The Si—N bond is 1.782 (2) Å, which is substanti­ally longer than is found in comparable (3,5-di­methyl­pyrazol­yl)silanes. The tri­methyl­silyl group adopts a staggered conformation with respect to the planar 3,5-di­methyl­pyrazolyl unit. C—H⋯N hydrogen bonds between neighboring mol­ecules form a strand of mol­ecules along the b-axis direction.

Publikationsfonds

Publikationsfonds

info:eu-repo/classification/ddc/540

ddc:540

Pyrazole

Siliciumorganische Verbindungen

Kristallstruktur

Ba(BO2OH) – A Monoprotonated Monoborate from Hydroflux Showing Intense Second Harmonic Generation

Li, Yuxi, Hegarty, Peter A., Rüsing, Michael, Eng, Lukas M., Ruck, Michael

30 May 2024

Pure samples of colorless, air-stable Ba(BO2OH) crystals were obtained from Ba(NO3)2 and H3BO3 under the ultra-alkaline conditions of a KOH hydroflux at about 250 °C. The product formation depends on the water-base molar ratio and the molar ratio of the starting materials. B(OH)3 acts as a proton donor (Brønsted acid) rather than a hydroxide acceptor (Lewis acid). Ba(BO2OH) crystallizes in the non-centrosymmetric orthorhombic space group P212121. Hydrogen bonds connect the almost planar (BO2OH)2− anions, which are isostructural to HCO3−, into a syndiotactic chain. IR and Raman spectroscopy confirm the presence of hydroxide groups, which are involved in weak hydrogen bonds. Upon heating in air to about 450 °C, Ba(BO2OH) dehydrates to Ba2B2O5. Moreover, the non-centrosymmetric structure of Ba(BO2OH) crystals was verified with power-dependent confocal Second Harmonic Generation (SHG) microscopy indicating large conversion efficiencies in ambient atmosphere.

info:eu-repo/classification/ddc/540

ddc:540

Binding modes of methyl α-d-glucopyranoside to an artificial receptor in crystalline complexes

Köhler, Linda, Hübler, Conrad, Seichter, Wilhelm, Mazik, Monika

09 July 2024

Compared to the numerous X-ray crystal structures of protein-carbohydrate complexes, the successful elucidation of the crystal structures of complexes between artificial receptors and carbohydrates has been very rarely reported in the literature. In this work, we describe the binding modes of two complexes formed between methyl α-D-glucopyranoside and an artificial receptor belonging to the class of compounds consisting of a 1,3,5-trisubstituted 2,4,6-trialkylbenzene scaffold. It is particularly noteworthy that these two complexes are present in one crystal structure, as was observed by us for the first time in the case of the recently reported three crystal structures of the complexes with methyl β-D-glucopyranoside, each containing two different receptor–carbohydrate complexes. The noncovalent interactions stabilizing the new complexes are compared with those observed in the aforementioned crystalline complexes with methyl β-D-glucopyranoside.

Publikationsfonds

publishing fund

info:eu-repo/classification/ddc/547

ddc:547

Acyclische Verbindungen

Pyrimidinderivate

Kristallstruktur

Wasserstoffbrückenbindung

Monosaccharide

Heterocyclische Verbindungen

Structural properties, deformation behavior and thermal stability of martensitic Ti-Nb alloys

Bönisch, Matthias

09 August 2016

Ti-Nb alloys are characterized by a diverse metallurgy which allows obtaining a wide palette of microstructural configurations and physical properties via careful selection of chemical composition, heat treatment and mechanical processing routes. The present work aims to expand the current state of knowledge about martensite forming Ti-Nb alloys by studying 15 binary Ti-c_{Nb}Nb (9wt.% ≤ c_{Nb} ≤ 44.5wt.%) alloy formulations in terms of their structural and mechanical properties, as well as their thermal stability. The crystal structures of the martensitic phases, α´ and α´´, and the influence of the Nb content on the lattice (Bain) strain and on the volume change related to the β → α´/α´´ martensitic transformations are analyzed on the basis of Rietveld-refinements. The magnitude of the shuffle component of the β → α´/α´´ martensitic transformations is quantified in relation to the chemical composition. The largest transformation lattice strains are operative in Nb-lean alloys. Depending on the composition, both a volume dilatation and contraction are encountered and the volume change may influence whether hexagonal martensite α´ or orthorhombic martensite α´´ forms from β upon quenching. The mechanical properties and the deformation behavior of martensitic Ti-Nb alloys are studied by complementary methods including monotonic and cyclic uniaxial compression, nanoindentation, microhardness and impulse excitation technique. The results show that the Nb content strongly influences the mechanical properties of martensitic Ti-Nb alloys. The elastic moduli, hardness and strength are minimal in the vicinity of the limiting compositions bounding the interval in which orthorhombic martensite α´´ forms by quenching. Uniaxial cyclic compressive testing demonstrates that the elastic properties of strained samples are different than those of unstrained ones. Also, experimental evidence indicates a deformation-induced martensite to austenite (α´´ → β) conversion. The influence of Nb content on the thermal stability and on the occurrence of decomposition reactions in martensitic Ti-Nb alloys is examined by isochronal differential scanning calorimetry, dilatometry and in-situ synchrotron X-ray diffraction complemented by transmission electron microscopy. The thermal decomposition and transformation behavior exhibits various phase transformation sequences during heating into the β-phase field in dependence of composition. Eventually, the transformation temperatures, interval, hysteresis and heat of the β ↔ α´´ martensitic transformation are investigated in relation to the Nb content. The results obtained in this study are useful for the development and optimization of β-stabilized Ti-based alloys for structural, Ni-free shape memory and/or superelastic, as well as for biomedical applications. / Ti-Nb Legierungen zeichnen sich durch eine vielfältige Metallurgie aus, die es nach sorgfältiger Auswahl der chemischen Zusammensetzung sowie der thermischen und mechanischen Prozessierungsroute ermöglicht eine große Bandbreite mikrostruktureller Konfigurationen und physikalischer Eigenschaften zu erhalten. Das Ziel der vorliegenden Arbeit ist es den gegenwärtigen Wissensstand über martensitbildende Ti-Nb Legierungen zu erweitern. Zu diesem Zweck werden 15 binäre Ti-c_{Nb} Nb (9 Gew.% ≤ c_{Nb} ≤ 44.5 Gew.%) Legierungen hinsichtlich ihrer strukturellen und mechanischen Eigenschaften sowie ihrer thermischen Stabilität untersucht. Die Kristallstrukturen der martensitischen Phasen, α´ und α´´, sowie der Einfluss des Nb-Gehalts auf die Gitterverzerrung (Bain-Verzerrung), auf die Verschiebungswellenkomponente (Shuffle-Komponente) und auf die Volumenänderung der martensitischen β → α´/α´´ Transformationen werden anhand von Rietveld-Verfeinerungen analysiert. In Abhängigkeit des Nb-Gehalts tritt entweder eine Volumendilatation oder -kontraktion auf, die bestimmen könnte ob hexagonaler Martensit α´ oder orthorhombischer Martensit α´´ aus β bei Abkühlung gebildet wird. Die mechanischen Eigenschaften und das Verformungsverhalten martensitischer Ti-Nb Legierungen werden mit einer Reihe komplementärer Methoden (monotone und zyklische einachsige Druckversuche, Nanoindentation, Mikrohärte, Impulserregungstechnik) untersucht. Die Ergebnisse zeigen durchgehend, dass die mechanischen Eigenschaften martensitischer Ti-Nb Legierungen stark vom Nb-Gehalt beeinflusst werden. Die mechanischen Kennwerte sind minimal in der Nähe der Zusammensetzungen, innerhalb derer β → α´´ bei Abkühlung auftritt. Aus Druckversuchen geht hervor, dass die elastischen Eigenschaften verformter Proben verschieden zu denen unverformter sind. Die experimentellen Ergebnisse weisen außerdem auf eine verformungsinduzierte Umwandlung von Martensit in Austenit (α´´ → β) hin. Der Einfluss des Nb-Gehalts auf die thermische Stabilität und das Auftreten von Zerfallsreaktionen in martensitischen Ti-Nb Legierungen wird anhand von dynamischer Differenzkalorimetrie, Dilatometrie, und in-situ Synchrotronröntgenbeugung in Kombination mit Transmissionselektronenmikroskopie untersucht. Das thermische Zerfalls- und Umwandlungsverhalten ist durch das Auftreten einer Vielzahl von in Abhängigkeit des Nb-Gehalts unterschiedlichen Phasentransformationssequenzen gekennzeichnet. Abschließend werden die Transformationstemperaturen und -wärmen, das Transformationsinterval und die thermische Hysterese der martensitischen β ↔ α´´ Umwandlung untersucht. Die Ergebnisse dieser Arbeit sind für die Entwicklung und Optimierung β-stabilisierter Ti-Legierungen für strukturelle und biomedizinische Anwendungen sowie Ni-freier Komponenten, die Formgedächtniseffekt und/oder Superelastizität aufweisen, von Nutzen.

Ti-Legierung

Martensit

Kristallstruktur

Elastizität

Phasentransformation

Ti-alloy

martensite

crystal structure

elasticity

phase transformation

ddc:530

rvk:UQ 3400

Übergangsmetallegierung

Martensitkristall

Struktur

Mechanische Eigenschaft

Phasentransformation

Structure Determination of Viscotoxin A1, Tendamistat and Tri Peptidyl peptidase-I / Strukturbestimmung von Viscotoxin A1, Tendamistat und Tripeptidyl Peptidase-I

Pal, Aritra

24 January 2008

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Vistotoxin

Tendamistat

crystal structure

SAD phasing

42.13

35.25

Crystallographic insights into (CH3NH3)3(Bi2I9): a new lead-free hybrid organic–inorganic material as a potential absorber for photovoltaics

Eckhardt, Kai, Bon, Volodymyr, Getzschmann, Jürgen, Grothe, Julia, Wisser, Florian M., Kaskel, Stefan

17 March 2017

The crystal structure of a new bismuth-based light-absorbing material for the application in solar cells was determined by single crystal X-ray diffraction for the first time. (CH3NH3)3(Bi2I9) (MBI) is a promising alternative to recently rapidly progressing hybrid organic–inorganic perovskites due to the higher tolerance against water and low toxicity. Single crystal X-ray diffraction provides detailed structural information as an essential prerequisite to gain a fundamental understanding of structure property relationships, while powder diffraction studies demonstrate a high degree of crystallinity in thin films.

Kristallstruktur

Einkristall-Röntgenbeugung

Pulverdiffraktionsuntersuchung

Photovoltaik

TU Dresden

Publikationsfonds

crystal structure

single crystal X-ray diffraction

powder diffraction studies

photovoltaic

TU Dresden

Publishing Fund

ddc:540

rvk:VA 1120