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Структура и динамика решетки редкоземельных германатов R2Ge2O7 (R=Tb-Lu, Y) : магистерская диссертация / Crystal structure and lattice dynamics of rare-earth germanates R2Ge2O7 (R=Tb-Lu, Y)Рюмшин, В. С., Ryumshin, V. S. January 2020 (has links)
Германаты R2Ge2O7 (R=Tb-Lu, Y) имеют широкую область применения благодаря многообразию свойств, в том числе, благодаря оптическим свойствам. Кристаллическая структура этих соединений изучена достаточно хорошо, в то время как экспериментальных данных по фононным спектрам и упругим постоянным нет. В научной печати имеются только данные об ИК и КР спектрах поликристаллического образца Y2Ge2O7, из которых были определены частоты менее половины фононных мод. В связи с этим представляется актуальным провести первопринципное исследование структуры и динамики ряда R2Ge2O7 (R=Tb-Lu, Y). В работе в рамках единого ab initio подхода были проведены расчеты кристаллической структуры, частот и интенсивностей ИК и КР спектров, а также упругих постоянных R2Ge2O7. Из анализа векторов смещений, полученных из первопринципного расчета, определена степень участия ионов в каждой моде. Расчет фононных спектров и упругих постоянных для редкоземельных германатов R2Ge2O7 выполнен впервые. Расчеты проводились в рамках теории функционала плотности с гибридным функционалом PBE0, который учитывает локальный и нелокальный (в формализме Хартри-Фока) обмен, а также межэлектронные корреляции. Такой подход надежно опробован для сложных соединений с ионной и ионно-ковалентной связью. Расчеты были проведены в программе CRYSTAL17, предназначенной для моделирования периодических структур в рамках МО ЛКАО подхода. Результаты расчетов R2Ge2O7 хорошо согласуются с экспериментальными данными по кристаллической структуре, а также с имеющимися данными по ИК и КР спектрам для Y2Ge2O7. Расчеты позволили определить типы мод в измеренных спектрах иттриевого германата, а также описать изменение частот фононных мод и упругих свойств соединений R2Ge2O7 в ряду R=Tb-Lu. / Germanates R2Ge2O7 (R = Tb-Lu, Y) have a wide area of applications due to the variety of properties, including optical properties. The crystal structure of these compounds has been studied quite well, but there are no experimental data of phonon spectra and elastic constants. In the articles only the IR and Raman spectra of the polycrystalline Y2Ge2O7 are available, from which the frequencies of less than half of the phonon modes were determined. In this regard, it seems actual to conduct ab-initio study of the structure and dynamics of the row R2Ge2O7 (R = Tb-Lu, Y). In the framework of a single ab initio approach were calculated the crystal structure, frequencies and intensities of the IR and Raman spectra and elastic constants of R2Ge2O7. From the analysis of displacement vectors obtained from an ab-initio calculation, the degree of participation of ions in each mode is determined. The calculation of phonon spectra and elastic constants for rare-earth germanates R2Ge2O7 was performed for the first time. The calculations were carried out in the framework of the density functional theory with the PBE0 hybrid functional, which takes into account local and nonlocal (in the Hartree-Fock formalism) exchange, as well as interelectronic correlations. This approach has been reliably tested for complex compounds with ion and ion-covalent bonds. The calculations were carried out in the CRYSTAL17 program, designed to simulate periodic structures within the framework of the MO LCAO approach. The results of calculations of R2Ge2O7 are in good agreement with the experimental data of the crystal structure and with the available data of IR and Raman spectra for Y2Ge2O7. The calculations made it possible to determine the types of modes in the measured spectra of yttrium germanate and to describe the change in the frequencies of the phonon modes and the elastic properties of R2Ge2O7 compounds in the row R = Tb-Lu.
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Open-Framework Germanates and Nickel Germanates : Synthesis and CharacterizationHuang, Shiliang January 2012 (has links)
Microporous materials have a wide range of important applications in separation, gas adsorption, ion-exchange and catalysis. Open-framework germanates are a family of microporous compounds and are of particular interest. This thesis focuses on the synthesis and characterization of new open-framework germanates as well as introducing the transition-metal nickel into germanate structures. One new microporous germanosilicate, SU-78 and four new open-framework germanates, SU-74, SU-75, SU-69 and SU-76 have been obtained by using organic molecules as structure directing agents (SDAs). The incorporation of nickel and organic SDAs in the synthesis resulted in five novel nickel germanates, SUT-1, SUT-2, SUT-3, SUT-4 and SUT-5, in which nickel complexes act either as framework-forming components or as structure directing agents. The general synthesis route is described and the variables that affect the synthesis products are summarized. Different techniques applied on the characterization of chemical and physical properties of the products are also introduced. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 1: Submitted. Paper 2: Submitted. Paper 3: Submitted. Paper 5: Manuscript.</p>
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Optical properties and laser induced fluorescence from BGO:RE waveguidesJazmati, A. K. January 1999 (has links)
No description available.
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Nuclear magnetic resonance studies of some germanate and phosphate based glassesHussin, Rosli Bin January 1998 (has links)
No description available.
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Preparation and humidity sensitive impedance of spinel ceramic nickel germanateHogan, Matthew John January 1999 (has links)
This thesis concerns the formation, sintering and humidity dependent electrical behaviour of the spinel ceramic material nickel germanate, Ni(_2)Ge0(_4).Ni(_2)Ge0(_4) has been prepared via the solid state reaction between NiO and GeO(_2) over a range of temperatures, and characterised using a number of techniques. The sintering behaviour of pressed pellets of Ni(_2)Ge0(_4) has also been investigated, together with a characterisation of the microstructure of the sintered bodies. Substitutional doping of Ni(_2)GeO(_4) with Li as a replacement for Ni is found to promote a high degree of shrinkage in the sintering process, probably due to the formation of a liquid phase. XRD revealed that even when 10 % of the Ni atoms were replaced with Li, no change in the crystal structure could be detected. A C. impedance spectroscopy of Ni(_2)Ge0(_4) samples was used to investigate the humidity sensitivity of this material. Equivalent circuit analysis, based on a network of resistors and constant phase elements, shows that the humidity sensitivity is due to conduction in a surface layer of water, in agreement with the models currently popular in the Uterature. Measurement of the water adsorption isotherm of Ni(_2)Ge0(_4) in pellet form indicates that a single monolayer of water is formed at around 20 %R(_H), with an approximately linear increase in water layer thickness up to around 80 %R(_H), after which capillary condensation causes a large increase in the volume of adsorbed water. The information gained on the thickness of this layer of water has been correlated with the resistance of the layer measured by impedance spectroscopy, and subsequently used to provide evidence for a model of the humidity sensitive conduction. The conduction in the surface layer is thought to be due to dissociation of the water, where the amount of dissociation is exponentially dependent on the humidity.
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Open-Framework Germanates : Synthesis, Structure, and CharacterizationInge, Andrew Kentaro January 2012 (has links)
Novel open-framework germanates and open low-dimensional structures were synthesized and characterized. Their crystal structures were solved by single crystal X-ray diffraction or X-ray powder diffraction combined with other techniques. Although related open-framework materials, such as zeolites, are of interest for the ability to selectively accommodate guest species in their rings, pores and channels, germanates are primarily of interest for their unique structural properties. Compared to aluminosilicate-based zeolites, germanium oxides readily form frameworks with extra-large rings and low framework density. The formation of elegant germanate architectures is attributed to the unique Ge-O bond geometries compared to Si-O, and the tendency to form large clusters. This thesis is to serve as an introduction to germanate synthesis, structures and characterization. Structures are categorized in accordance to their building units; the Ge7X19 (Ge7), Ge9X25-26 (Ge9) and Ge10X28 (Ge10) (X = O, OH, or F) clusters. Structure determination techniques as well as the characterization techniques used to examine the properties of the materials are presented. While most of the discussed techniques have routinely been used to study crystalline open-frameworks, we introduce the use of infrared spectroscopy for the identification of cluster types, valuable for structure determination by X-ray powder diffraction. Structures and properties of the novel materials ASU-21, SU-62, SU-63, SU-64, SU-65, SU-66, SU-71, SU-72, SU-73, SU-74, SU-75 and SU-JU-14 are described and put into context with previously known structures. The novel structures are all built of the Ge7, Ge9 or Ge10 clusters, and vary from a framework with novel topology to the first open zero-dimensional germanate cavities built of such clusters. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: Submitted. Paper 3: Manuscript. Paper 4: Submitted. Paper 6: Submitted. Paper 7: Manuscript. Paper 8. Manuscript. Paper 10: Unpublished book chapter.</p><p> </p>
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Nuclear Magnetic Resonance Studies of Disorder and Local Structure in Borate and Germanate MaterialsMichaelis, Vladimir K. 14 December 2010 (has links)
Glass materials surround us, impacting our lives on a daily basis, whether geologically deposited by volcanic activity or synthesized in large volume by industry. These amorphous oxide materials are vastly important due to their variety of applications including solid electrolytes, cookware, and storage of high-level nuclear waste. Although they are used for different applications, one common characteristic of these materials is the absence of long-range periodic order. This makes it difficult to use traditional solid-state characterization methods such as x-ray and neutron diffraction to study glass structure. Nuclear magnetic resonance (NMR), is ideally suited to study materials that exhibit short-range non-periodic order as it probes directly at a nucleus of interest and is sensitive to its local structural environment. This ability of solid-state NMR is illustrated by revealing local structural features in various oxide materials presented in this thesis. Within is a compilation of studies looking at basic borates, followed by borovanadates and complex borosilicate glasses. A multinuclear application of using quantum chemical calculations, single and double resonance methods and charge-balance models are discussed to deconvolute the complex structures of these disordered materials. This is followed by a study of a difficult low-gamma nucleus, 73Ge, (once considered “impossible” for solid-state NMR) which is explored for future material studies by looking at 73Ge NMR of crystalline and glassy germanates. 73Ge chemical shifts were related to coordination environments and quadrupolar coupling constants were related to bond length distortions.
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Nuclear Magnetic Resonance Studies of Disorder and Local Structure in Borate and Germanate MaterialsMichaelis, Vladimir K. 14 December 2010 (has links)
Glass materials surround us, impacting our lives on a daily basis, whether geologically deposited by volcanic activity or synthesized in large volume by industry. These amorphous oxide materials are vastly important due to their variety of applications including solid electrolytes, cookware, and storage of high-level nuclear waste. Although they are used for different applications, one common characteristic of these materials is the absence of long-range periodic order. This makes it difficult to use traditional solid-state characterization methods such as x-ray and neutron diffraction to study glass structure. Nuclear magnetic resonance (NMR), is ideally suited to study materials that exhibit short-range non-periodic order as it probes directly at a nucleus of interest and is sensitive to its local structural environment. This ability of solid-state NMR is illustrated by revealing local structural features in various oxide materials presented in this thesis. Within is a compilation of studies looking at basic borates, followed by borovanadates and complex borosilicate glasses. A multinuclear application of using quantum chemical calculations, single and double resonance methods and charge-balance models are discussed to deconvolute the complex structures of these disordered materials. This is followed by a study of a difficult low-gamma nucleus, 73Ge, (once considered “impossible” for solid-state NMR) which is explored for future material studies by looking at 73Ge NMR of crystalline and glassy germanates. 73Ge chemical shifts were related to coordination environments and quadrupolar coupling constants were related to bond length distortions.
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Open-framework Structures Built by Inorganic Clusters : Synthesis and CharacterizationChen, Hong January 2014 (has links)
Novel open-framework germanates and vanadoborates, which are constructed from typical types of clusters, have been synthesized based on different strategies. The crystal structures are solved by using single crystal X-ray diffraction (SXRD) technique or by combined techniques. Additionally, the structures of two open-framework materials, PKU-3 and PKU-16, are determined from nano-sized crystals by rotation electron diffraction (RED) combined with powder X-ray diffraction (PXRD). This thesis serves as an introduction to synthesis of open-framework germanates and vanadoborates based on different design strategies. Two germanates are obtained; SU-74 is achieved by employing a novel structure directing agent (SDA), SUT-8 is achieved by assembling the novel structure building units (SBUs) of Co@Ge14 with the introduction of cobalt ions in the synthesis. Four strategies are successfully used in construction of open-framework vanadoborates: using metal-oxo polyhedra as the linkages in SUT-6; applying the scale chemistry approach in SUT-7; employing metal-organic complexes as the linkages in SUT-12, SUT-13, SUT-14; and introducing covalent bond organic linkages into SUT-10 and SUT-11. Single crystal X-ray diffraction is used to conduct the structure determination in combination with other techniques. Furthermore, the structures of two open-framework materials, an aluminoborate PKU-3 and a germanosilicate PKU-16, are solved from nano-sized crystals using RED data. The structures are further confirmed by Rietveld refinement against PXRD data. The advantages of the RED techniques are demonstrated in two aspects. In PKU-3, the presence of seriously preferred orientation and light elements in the structure makes it difficult for structure determination by PXRD, but it is easier by RED. In PKU-16, the RED technique is used to determine its structure from the as-synthesized multi-phasic sample containing nano-sized crystals. After the structure of PKU-16 has been solved, the synthesis of this interesting phase can be optimized and pure PKU-16 can be obtained. Keywords: Open-framework, germanates, vanadoborates, aluminoborates, germanosilicates, crystal structure, hydrothermal synthesis, single crystal X-ray diffraction, rotation electron diffraction, powder X-ray diffraction
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From molecular germanates to microporous Ge@C via twin polymerizationKitschke, Philipp, Walter, Marc, Rüffer, Tobias, Lang, Heinrich, Kovalenko, Maksym V., Mehring, Michael 31 March 2016 (has links) (PDF)
Four molecular germanates based on salicyl alcoholates, bis(dimethylammonium) tris[2-(oxidomethyl)phenolate(2-)]germanate (1), bis(dimethylammonium) tris[4-methyl-2-(oxidomethyl)phenolate(2-)]germanate (2), bis(dimethylammonium) tris[4-bromo-2-(oxidomethyl)phenolate(2-)]germanate (3) and dimethylammonium bis[2-tert-butyl-4-methyl-6-(oxidomethyl)phenolate(2-)][2-tert-butyl-4-methyl-6-(hydroxymethyl)phenolate(1-)]germanate (4), were synthesized and characterized including single crystal X-ray diffraction analysis. In the solid state, compounds 1 and 2 exhibit one-dimensional hydrogen bonded networks, whereas compound 4 forms separate ion pairs, which are connected by hydrogen bonds between the dimethylammonium and the germanate moieties. The potential of these compounds for thermally induced twin polymerization (TP) was studied. Germanate 1 was converted by TP to give a hybrid material (HM-1) composed of phenolic resin and germanium dioxide. Subsequent reduction with hydrogen provided a microporous composite containing crystalline germanium and carbon (Ge@C – C-1, germanium content ∼20%). Studies on C-1 as an anode material for Li-ion batteries revealed reversible capacities of ∼370 mA h gGe@C−1 at a current density up to 1384 mA g−1 without apparent fading for 500 cycles. / Dieser Beitrag ist aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.
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