Die Analyse der Sauerstofftoleranz und biotechnologische Anwendung der NAD+-reduzierenden Hydrogenase aus Ralstonia eutropha H16

Lauterbach, Lars

30 May 2014

Die NAD+-reduzierende Hydrogenase aus Ralstonia eutropha (SH) katalysiert die reversible H2-Oxidation in Verbindung mit der Reduktion von NAD+ in Gegenwart von Sauerstoff. Die bemerkenswerte O2-Toleranz des Enzyms wurde zuvor auf eine für [NiFe]-Hydrogenasen ungewöhnliche Struktur des Wasserstoff-spaltenden Zentrums zurückgeführt. Diese Hypothese wurde in dieser Arbeit mittels in situ-Spektroskopie an SH-haltigen Zellen widerlegt. Um die folgende Untersuchung der aus sechs Untereinheiten und mindestens acht Kofaktoren bestehenden SH zu erleichtern, wurde das Enzym mittels genetischer Methoden in seine beiden Module aufgeteilt. Das die H2-Oxidation katalysierende Hydrogenase-Modul beinhaltete ein FMN-Molekül, welches für die reduktive Reaktivierung des oxidativ modifizierten Zentrums benötigt wird. Das Diaphorase-Modul besaß ebenfalls ein FMN, und die Reduktion von NAD+ wurde von der Anwesenheit von O2 nicht beeinträchtigt. Neben Wasserstoff reagierte das [NiFe]-Zentrum der SH auch mit Sauerstoff. Dabei wurde sowohl Wasserstoffperoxid- als auch Wasser im Hydrogenase-Modul freigesetzt. Die Sauerstofftoleranz der SH basiert auf einer kontinuierlichen Reaktivierung des durch Sauerstoff oxidierten [NiFe]-Zentrums. Aufgrund der außergewöhnlichen Sauerstofftoleranz stellt die SH ein vielversprechendes System für die wasserstoffgetriebene Regeneration von NADH in gekoppelten enzymatischen Reaktionen dar. In dieser Arbeit wurde ein SH-Derivat durch rationale Mutagenese konstruiert, das in der Lage war, ebenso den Kofaktor NADP+ wasserstoffabhängig zu reduzieren. Durch Ganzzellansätze kann die zeitaufwändige und kostenintensive Proteinreinigung vermieden werden. Um die wasserstoffabhängige in-vivo-Kofaktorregeneration zu ermöglichen, wurde die SH in Pseudomonas putida heterolog produziert. Die in dieser Arbeit erzielten Ergebnisse sind sowohl für das molekulare Verständnis der H2-abhängigen Katalyse als auch für die biotechnologische Anwendung der O2-toleranten SH relevant. / The NAD+ reducing hydrogenase from Ralstonia eutropha (SH) catalyzes the reversible oxidation of hydrogen in connection with the reduction of NAD+ in the presence of oxygen. The remarkable oxygen tolerance was previously related to an unusual [NiFe] active site with four instead of two cyanide ligands. This hypothesis was rejected in this study by using in situ spectroscopy on SH containing cells. To simplify the investigation of the six-subunit and at least eight cofactors containing SH, the enzyme was separated into its two modules by genetic methods. The hydrogen oxidizing hydrogenase module contained one FMN molecule, which was required for the reductive reactivation of the oxidatively modified active site. The diaphorase module carried a second FMN. The reduction of NAD+ was not affected by the presence of oxygen. In addition to hydrogen, the [NiFe] center of the SH reacted with oxygen. Both hydrogen peroxide and water were released by the hydrogenase module. The oxygen tolerance of the SH is based on a continuous reactivation of the oxidized [NiFe] center. Due to the oxygen tolerance, the SH is a promising system for hydrogen based NADH regeneration in coupled enzymatic reactions. In this study a SH derivative was constructed by means of rational mutagenesis. The SH derivative was able to reduce the cofactor NADP+ by hydrogen oxidation. The time consuming and costly protein purification can be avoided by using whole cell approaches. In order to allow the hydrogen dependent in vivo cofactor regeneration, SH was heterologously produced in Pseudomonas putida. The results obtained in this study are relevant for the molecular understanding of hydrogen dependent catalysis and for the biotechnological application of the oxygen tolerant SH.

Elektrochemie

Wasser

Hydrogenase

Eisen-Schwefel-Cluster

Ralstonia eutropha

Sauerstofftoleranz

Aktives Zentrum

NADH-Regeneration

Diaphorase

FTIR

Komplex I

FMN

Flavinmononukleotid

Wasserstoffperoxid

FTIR

electrochemistry

water

oxygen tolerance

Ralstonia eutropha

active site

hydrogenase

NADH regeneration

diaphorase

Complex I

Fe-S Cluster

FMN

flavin mononucleotide

hydrogen peroxide

570 Biowissenschaften, Biologie

32 Biologie

WD 5050

ddc:570

On Ternary Phases of the Systems RE–B–Q (RE = La – Nd, Sm, Gd – Lu, Y; Q = S, Se)

Borna, Marija

15 October 2012

It is known that boron containing compounds exhibit interesting chemical and physical properties. In the past 50 years modern preparative methods have led to an overwhelming number of different structures of novel and often unexpected boron–sulfur and boron–selenium compounds. Among all these new compounds, there was only one which comprises rare earth metal (RE), boron and heavier chalcogen, namely sulfur, the europium thioborate Eu[B2S4] [1]. Selenoborates of rare earth metals are hitherto unknown. On the other hand, rare earth oxoborates represent a well-known class of compounds [2] with a wide range of applications, especially in the field of optical materials. In addition, well-defined boron compounds containing the heavier group 16 elements are fairly difficult to prepare due to the high reactivity of in situ formed boron chalcogenides towards most container materials at elevated temperatures. The chalcogenoborates of the heavier chalcogens are sensitive against oxidation and hydrolysis and therefore have to be handled in an inert environment. Therefore, developing and optimization of preparative routes for the syntheses of pure and crystalline RE thio- and selenoborates was needed. In the course of this study, the application of different preparation routes, such as optimized high-temperature routes (HT), metathesis reactions and high-pressure high-temperature routes (Hp – HT), led to sixteen new rare earth thioborates. Their crystal structures were solved and/or refined from powder and single crystal X-ray diffraction data, while the local structure around rare earth metal was confirmed from the results of the EXAFS analyses. Quantum mechanical calculations were used within this work in order to investigate the arrangement of intrinsic vacancies on the boron sites in the crystal structures of rare earth thioborates. Thermal, magnetic and optical properties of these compounds are also discussed. The rare earth thioborates discovered during this work are the first examples of ternary thioborates containing trivalent cations. These compounds can be divided into two groups of isotypic compounds: the rare earth orthothioborates with general formula REIII[BS3] (RE = La – Nd, Sm, Gd and Tb) [3] and the rare earth thioborate sulfides with general formula REIII¦9B5S21, (RE = Gd – Lu, and Y) [4]. In the crystal structure of RE[BS3] (orthorhombic, space group Pna21, Z = 4), the sulfur atoms form the vertices of corrugated kagome nets, within which every second triangle is occupied by boron and the large hexagons are centered by RE cations. The structural features of the isotypic RE[BS3] phases show great similarities to those of rare earth oxoborates RE[BO3] and orthothioborates of alkali and alkaline earth metals as well as to thallium orthothioborate, yet pronounced differences are also observed: the [BS3]3– groups in the crystal structures of RE[BS3] are more distorted, where the distortion decreases with the decreasing size of the RE element, and the coordination environments of the [BS3]3– groups in the crystal structures of RE[BS3] are different in comparison with the coordination environments of the [BO3]3– groups in the crystal structures of λ-Nd[BO3] [5] and of o-Ce[BO3] [6]. The results of the IR and Raman investigations are in agreement with the presence of [BS3]3– anions in the crystal structure of RE[BS3]. Thermal analyses revealed the thermal stability of these compounds under inert conditions up to ~ 1200 K. Analyses of the magnetic properties of the Sm, Gd and Tb thioborates showed that both Gd and Tb phases order antiferromagnetically. The magnetic susceptibility for Sm orthothioborate approximately follows the Van-Vleck theory for Sm3+. Between 50 K and 62 K a transition appears which is independent of the magnetic field: the magnetic susceptibility becomes lower. This effect might indicate a discontinuous valence transition of Sm which was further investigated by means of XANES and X-ray diffraction using synchrotron radiation, both at low temperatures. The series of isotypic RE thioborate sulfides with composition RE9B5S21, was obtained by the application of Hp – HT conditions to starting mixtures with the initial chemical composition “REB3S6“, after careful optimization of the pressure, temperature and treatment time, as well as the composition of the starting mixtures. Their crystal structures adopt the Ce6Al3.33S14 [7] structure type (hexagonal, space group P63, Z = 2/3). The special features of the RE9B5S21 crystal structures, concerning boron site occupancies and different coordination environments of the two crystallographically independent boron sites, were investigated in more detail by means of quantum chemical calculations, electron diffraction methods, optical and X-ray absorption spectroscopy as well as by 11B NMR spectroscopy. The results obtained from these different experimental and computational methods are in good mutual agreement. The crystal structures of the RE9B5S21 compounds are characterized by two types of anions: tetrahedral [BS4]5– and trigonal planar [BS3]3– as well as [(S2–)3] units. Isolated [BS4]5– tetrahedra (all pointing with one of their apices along the polar [001] direction) represent a unique feature of the crystal structure which is observed for the first time in a thioborate compound. These tetrahedra are stacked along the three-fold rotation axes. Vacancies are located at the trigonal-planar coordinated boron site with preferred ordering –B–B––B–B–– along [001]. No superstructure is observed by means of electron diffraction methods as adjacent columns are shuffled along the c axis, giving rise to a randomly distributed vacancy pattern. Positions of the sulfur atoms within the [(S2–)3] substructure as well as planarity of the [BS3]3– units were investigated in more detail by means of quantum mechanical calculations. Results of the IR and Raman spectroscopy, as well as of the 11B NMR spectroscopy are in agreement with the presence of the boron atoms in two different coordination environments. Thermal analyses showed that compounds RE9B5S21 are stable under inert conditions up to ~ 1200 K. In accordance with the combined results of experimental and computational investigations, the chemical formula of the RE9B5S21 compounds is consistent with RE3[BS3]2[BS4]3S3. A short overview of investigations towards rare earth selenoborates, where in most of the cases only known binary rare earth selenides could be identified, is presented as well in this work. Investigations in the RE–B–Se systems were conducted by the application of different preparation routes by varying the experimental parameters and the initial compositions of the starting mixtures. Although no crystal structure of a ternary phase in these systems could be solved, there are indications that such phases exist, but further investigations are needed. [1] M. Döch, A. Hammerschmidt, B. Krebs, Z. Anorg. Allg. Chem., 2004, 630, 519. [2] H. Huppertz, Chem. Commun., 2011, 47, 131; and references therein. [3] J. Hunger, M. Borna, R. Kniep, J. Solid State Chem., 2010, 182, 702; J. Hunger, M. Borna, R. Kniep, Z. Kristallogr. NCS, 2010, 225, 217; M. Borna, J. Hunger, R. Kniep, Z. Kristallogr. NCS, 2010, 225, 223; M. Borna, J. Hunger, R. Kniep, Z. Kristallogr. NCS, 2010, 225, 225. [4] M. Borna, J. Hunger, A. Ormeci, D. Zahn, U. Burkhardt, W. Carrillo-Cabrera, R. Cardoso-Gil, R. Kniep, J. Solid State Chem., 2011, 184, 296; [5] H. Müller-Bunz, T. Nikelski, Th. Schleid, Z. Naturforsch. B, 2003, 58, 375. [6] H. U. Bambauer, J. Weidelt, J.-St. Ysker, Z. Kristallogr., 1969, 130, 207. [7] D. de Saint-Giniez, P. Laruelle, J. Flahaut, C. R. Séances, Acad. Sci. Ser. C, 1968, 267, 1029.

Seltenerden chalcogenoborate

Seltenerden elemente

Hoch-Druck Hoch-Temperatur Synthese

Bor

Schwefel

Röntgen Diffraktometrie

XAS

Metathese Reaktionen

IR Spektroskopie

Raman Spektroskopie

Thermogravimetrische Analyse

Rare earth chalcogenoborates

Rare earth elements

High-pressure high-temperature synthesis

Boron

Sulfur

X-ray diffraction

XAS

Metathesis reaction

IR spectroscopy

Raman spectroscopy

Thermogravimetric analysis

ddc:540

rvk:VE 9507

Structural characterization of the lysosomal 66.3 kDa protein and of the DNA repair enzyme Mth0212 by means of X-ray crystallography / Strukturelle Charakterisierung des lysosomalen 66.3 kDa Proteins und des DNA-Reparaturenzyms Mth0212 mittels Röntgenkristallographie

Lakomek, Kristina

28 April 2009

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

66.3 kDa Protein

lysosomale Proteine

Glycosylierung

N-terminal nucleophile Hydrolasen

Autoproteolytische Aktivierung

Schwefel-SAD

DNA-Schaden

DNA-Reparatur

ExoIII-Homolog

2`-Desoxyuridin

Kristallstruktur

Röntgenkristallographie

66.3 kDa protein

lysosomal protein

glycosylation

N-terminal nucleophile hydrolase

autoproteolytic activation

sulfur SAD

DNA damage

DNA repair

ExoIII homolog

2`-deoxyuridine

crystal structure

X-ray crystallography

42.13

WF 200: Molekularbiologie

Mehrlingspolymerisation in Substanz und an Oberflächen zur Synthese nanostrukturierter und poröser Materialien

Ebert, Thomas

07 November 2016

Die vorliegende Arbeit befasst sich mit der Synthese und Charakterisierung von unterschiedlichen nanostrukturierten Hybridmaterialien ausgehend von nur einem Monomer. Dabei wird ein neuartiges Monomer vorgestellt, welches in einem Prozessschritt ein Hybridmaterial bestehend aus drei Polymeren bilden kann. Dies erweitert das Konzept der Zwillingspolymerisation, bei der zwei Polymere aus einem Monomer erhalten werden. Aus diesem Grund wurde der Überbegriff „Mehrlingspolymerisation“ für die Synthese von zwei oder mehr Polymeren aus nur einem Monomer eingeführt. Ein weiterer Schwerpunkt lag auf der gezielten Beschichtung verschiedener Partikeloberflächen mit nanostrukturierten Hybridmaterialien mittels Zwillingspolymerisation. Dabei wird der Einfluss der Oberfläche auf die Polymerisation verschiedener Zwillingsmonomere untersucht. Durch Nachbehandlung sind daraus poröse Kompositmaterialien zugänglich. Je nach Beständigkeit der Substrate sind diese in den Nachbehandlungsschritten stabil oder werden entfernt und dienen nur als Template zur Strukturierung der porösen Materialien. Es wurden unterschiedliche poröse Kohlenstoffe und Kohlenstoffkompositmaterialien hergestellt und charakterisiert. Ausgewählte Materialien wurden mit Schwefel verschmolzen und in Lithium-Schwefel-Zellen untersucht (Kooperation Dr. S. Choudhury, Leibniz-Institut für neue Materialien Saarbrücken). Die Charakterisierung der Proben erfolgte unter anderem mithilfe der Festkörper-NMR-Spektroskopie, Elektronenmikroskopie, dynamischen Differenzkalorimetrie, Röntgenpulver-diffraktometrie, Infrarotspektroskopie, Raman-Spektroskopie, Thermogravimetrie und Stickstoffsorption.

info:eu-repo/classification/ddc/540

ddc:540

On Ternary Phases of the Systems RE–B–Q (RE = La – Nd, Sm, Gd – Lu, Y; Q = S, Se)

Borna, Marija

13 August 2012

It is known that boron containing compounds exhibit interesting chemical and physical properties. In the past 50 years modern preparative methods have led to an overwhelming number of different structures of novel and often unexpected boron–sulfur and boron–selenium compounds. Among all these new compounds, there was only one which comprises rare earth metal (RE), boron and heavier chalcogen, namely sulfur, the europium thioborate Eu[B2S4] [1]. Selenoborates of rare earth metals are hitherto unknown. On the other hand, rare earth oxoborates represent a well-known class of compounds [2] with a wide range of applications, especially in the field of optical materials. In addition, well-defined boron compounds containing the heavier group 16 elements are fairly difficult to prepare due to the high reactivity of in situ formed boron chalcogenides towards most container materials at elevated temperatures. The chalcogenoborates of the heavier chalcogens are sensitive against oxidation and hydrolysis and therefore have to be handled in an inert environment. Therefore, developing and optimization of preparative routes for the syntheses of pure and crystalline RE thio- and selenoborates was needed. In the course of this study, the application of different preparation routes, such as optimized high-temperature routes (HT), metathesis reactions and high-pressure high-temperature routes (Hp – HT), led to sixteen new rare earth thioborates. Their crystal structures were solved and/or refined from powder and single crystal X-ray diffraction data, while the local structure around rare earth metal was confirmed from the results of the EXAFS analyses. Quantum mechanical calculations were used within this work in order to investigate the arrangement of intrinsic vacancies on the boron sites in the crystal structures of rare earth thioborates. Thermal, magnetic and optical properties of these compounds are also discussed. The rare earth thioborates discovered during this work are the first examples of ternary thioborates containing trivalent cations. These compounds can be divided into two groups of isotypic compounds: the rare earth orthothioborates with general formula REIII[BS3] (RE = La – Nd, Sm, Gd and Tb) [3] and the rare earth thioborate sulfides with general formula REIII¦9B5S21, (RE = Gd – Lu, and Y) [4]. In the crystal structure of RE[BS3] (orthorhombic, space group Pna21, Z = 4), the sulfur atoms form the vertices of corrugated kagome nets, within which every second triangle is occupied by boron and the large hexagons are centered by RE cations. The structural features of the isotypic RE[BS3] phases show great similarities to those of rare earth oxoborates RE[BO3] and orthothioborates of alkali and alkaline earth metals as well as to thallium orthothioborate, yet pronounced differences are also observed: the [BS3]3– groups in the crystal structures of RE[BS3] are more distorted, where the distortion decreases with the decreasing size of the RE element, and the coordination environments of the [BS3]3– groups in the crystal structures of RE[BS3] are different in comparison with the coordination environments of the [BO3]3– groups in the crystal structures of λ-Nd[BO3] [5] and of o-Ce[BO3] [6]. The results of the IR and Raman investigations are in agreement with the presence of [BS3]3– anions in the crystal structure of RE[BS3]. Thermal analyses revealed the thermal stability of these compounds under inert conditions up to ~ 1200 K. Analyses of the magnetic properties of the Sm, Gd and Tb thioborates showed that both Gd and Tb phases order antiferromagnetically. The magnetic susceptibility for Sm orthothioborate approximately follows the Van-Vleck theory for Sm3+. Between 50 K and 62 K a transition appears which is independent of the magnetic field: the magnetic susceptibility becomes lower. This effect might indicate a discontinuous valence transition of Sm which was further investigated by means of XANES and X-ray diffraction using synchrotron radiation, both at low temperatures. The series of isotypic RE thioborate sulfides with composition RE9B5S21, was obtained by the application of Hp – HT conditions to starting mixtures with the initial chemical composition “REB3S6“, after careful optimization of the pressure, temperature and treatment time, as well as the composition of the starting mixtures. Their crystal structures adopt the Ce6Al3.33S14 [7] structure type (hexagonal, space group P63, Z = 2/3). The special features of the RE9B5S21 crystal structures, concerning boron site occupancies and different coordination environments of the two crystallographically independent boron sites, were investigated in more detail by means of quantum chemical calculations, electron diffraction methods, optical and X-ray absorption spectroscopy as well as by 11B NMR spectroscopy. The results obtained from these different experimental and computational methods are in good mutual agreement. The crystal structures of the RE9B5S21 compounds are characterized by two types of anions: tetrahedral [BS4]5– and trigonal planar [BS3]3– as well as [(S2–)3] units. Isolated [BS4]5– tetrahedra (all pointing with one of their apices along the polar [001] direction) represent a unique feature of the crystal structure which is observed for the first time in a thioborate compound. These tetrahedra are stacked along the three-fold rotation axes. Vacancies are located at the trigonal-planar coordinated boron site with preferred ordering –B–B––B–B–– along [001]. No superstructure is observed by means of electron diffraction methods as adjacent columns are shuffled along the c axis, giving rise to a randomly distributed vacancy pattern. Positions of the sulfur atoms within the [(S2–)3] substructure as well as planarity of the [BS3]3– units were investigated in more detail by means of quantum mechanical calculations. Results of the IR and Raman spectroscopy, as well as of the 11B NMR spectroscopy are in agreement with the presence of the boron atoms in two different coordination environments. Thermal analyses showed that compounds RE9B5S21 are stable under inert conditions up to ~ 1200 K. In accordance with the combined results of experimental and computational investigations, the chemical formula of the RE9B5S21 compounds is consistent with RE3[BS3]2[BS4]3S3. A short overview of investigations towards rare earth selenoborates, where in most of the cases only known binary rare earth selenides could be identified, is presented as well in this work. Investigations in the RE–B–Se systems were conducted by the application of different preparation routes by varying the experimental parameters and the initial compositions of the starting mixtures. Although no crystal structure of a ternary phase in these systems could be solved, there are indications that such phases exist, but further investigations are needed. [1] M. Döch, A. Hammerschmidt, B. Krebs, Z. Anorg. Allg. Chem., 2004, 630, 519. [2] H. Huppertz, Chem. Commun., 2011, 47, 131; and references therein. [3] J. Hunger, M. Borna, R. Kniep, J. Solid State Chem., 2010, 182, 702; J. Hunger, M. Borna, R. Kniep, Z. Kristallogr. NCS, 2010, 225, 217; M. Borna, J. Hunger, R. Kniep, Z. Kristallogr. NCS, 2010, 225, 223; M. Borna, J. Hunger, R. Kniep, Z. Kristallogr. NCS, 2010, 225, 225. [4] M. Borna, J. Hunger, A. Ormeci, D. Zahn, U. Burkhardt, W. Carrillo-Cabrera, R. Cardoso-Gil, R. Kniep, J. Solid State Chem., 2011, 184, 296; [5] H. Müller-Bunz, T. Nikelski, Th. Schleid, Z. Naturforsch. B, 2003, 58, 375. [6] H. U. Bambauer, J. Weidelt, J.-St. Ysker, Z. Kristallogr., 1969, 130, 207. [7] D. de Saint-Giniez, P. Laruelle, J. Flahaut, C. R. Séances, Acad. Sci. Ser. C, 1968, 267, 1029.:I INTRODUCTION ......................................................................... 7 1. Motivation and scope of the work .............................................. 9 2. Literature overview .................................................................. 11 2.1. The binary subsystems of the ternary systems RE–B–Q (RE = rare earth metals, Y; Q = S, Se) ......................................................... 12 2.1.1. RE–Q ............................................................................... 12 2.1.2. RE–B ............................................................................... 19 2.1.3. B–Q ................................................................................. 22 2.2. Related ternary compounds ................................................... 25 2.2.1. RE oxoborates .................................................................. 25 2.2.2. Thio- and selenoborates of alkaline, alkaline earth, transition and post transition metals ......................................................................... 33 2.2.3. The RE thioborate Eu[B2S4]................................................ 45 II PREPARATIVE METHODS AND EXPERIMENTAL TECHNIQUES .......... 47 1. Starting materials and their characterization ............................... 49 2. Synthetic approaches and optimizations .................................... 51 2.1. High-temperature routes ...................................................... 52 2.2. Metathesis reactions ............................................................ 53 2.3. Spark Plasma Sintering (SPS) ............................................... 54 2.4. High-Pressure High-Temperature (Hp – HT) Syntheses ........... 55 3. Analytical methods and samples characterization ....................... 55 3.1. Powder X-ray diffraction ...................................................... 55 3.2. Crystal structure investigations using synchrotron radiation .... 57 3.3. Single crystal X-ray diffraction analysis .................................. 57 3.4. Metallographic investigations ................................................ 58 3.5. Electron microscopy ............................................................ 58 3.5.1. Scanning electron microscopy and energy dispersive X-ray spectroscopy ............................................................................ 58 3.5.2. Transmission electron microscopy ...................................... 59 3.6. Optical spectroscopy ........................................................... 59 3.6.1. Infra-Red spectroscopy .................................................... 59 3.6.2. Raman spectroscopy ........................................................ 60 3.7. X-ray absorption spectroscopy ............................................ 60 3.8. Thermal analysis ................................................................. 62 3.9. Magnetic susceptibility measurements ................................... 63 3.10. 11B NMR spectroscopy ..................................................... 63 3.11. Quantum chemical calculations ........................................... 64 3.11.1. Total energy calculations ................................................ 64 3.11.2. Charge transfer analysis ................................................ 64 3.11.3. Chemical bonding........................................................... 64 III RARE EARTH THIOBORATES ................................................. 67 1. Reinvestigation of the only reported rare earth thioborate – EuB2S4 ....69 2. RE[BS3] (RE = La – Nd, Sm, Gd, Tb) .................................... 69 2.1. Syntheses and phase analyses .......................................... 70 2.2. Crystal structure determinations ........................................ 74 2.3. X-ray absorption spectroscopy: EXAFS data analysis for Pr[BS3] ..... 79 2.4. Crystal chemistry .............................................................. 80 2.5. Optical spectroscopy ......................................................... 83 2.6. Thermal analysis ............................................................... 86 2.7. Magnetic susceptibility ....................................................... 88 2.8. X-ray absorption spectroscopy: XANES data analysis for Sm[BS3] .. 91 2.9. Crystal structure investigation at low temperature using synchrotron radiation ................................................................................... 91 2.10. Summary ......................................................................... 95 3. Gd[BS3] : Ce, Eu, Tb ............................................................. 97 3.1. Syntheses and phase analyses ............................................. 97 3.2. Crystal structure determinations ......................................... 101 3.3. Crystal chemistry .............................................................. 103 3.4. Optical spectroscopy ......................................................... 104 3.5. Thermal analysis ............................................................... 106 3.6. Summary ......................................................................... 107 4. RE9B5S21 (RE = Tb – Lu, Y) ................................................ 107 4.1. Syntheses and phase analyses ........................................... 108 4.2. Crystal structure determinations ........................................ 109 4.3. Crystal chemistry .............................................................. 112 4.4. Electronic structure, charge transfer and chemical bonding .... 115 4.5. X-ray absorption spectroscopy: EXAFS data analysis for Lu9B5S21 .............................................................................. 119 4.6. Thermal analysis ............................................................... 121 4.7. 11B NMR investigations ..................................................... 122 4.8. Optical spectroscopy ......................................................... 123 4.9. Summary ......................................................................... 126 IV ON THE WAY TO RARE EARTH SELENOBORATES .................... 127 1. Towards ternary phases in the systems RE–B–Se, with RE = Sm, Tb – Lu.......................................................................................... 129 2. The system La–B–Se ........................................................... 134 3. The system Gd–B–Se .......................................................... 136 4. The system Y–B–Se ............................................................ 137 5. Summary ........................................................................... 139 V SUMMARY AND OUTLOOK ..................................................... 141 VI APPENDIX .......................................................................... 149 VII REFERENCES .................................................................... 163 VIII LIST OF FIGURES ............................................................. 181 IX LIST OF TABLES ................................................................ 193 X CURRICULUM VITAE ........................................................... 199 XI VERSICHERUNG ............................................................... 203

info:eu-repo/classification/ddc/540

ddc:540

Syntheses and Electron Density Determination of Novel Polyimido Sulfur Ylides / Synthesen und Elektronendichtebestimmung an neuen Polyimido-Schwefelyliden

Deuerlein, Stephan

31 October 2007

No description available.

540 Chemie

Mathematics and Computer Science

Schwefelylide

Organolithiumchemie

Ladungsdichte

Bindung

QTAIM

ylidisch

ylenisch

Metallcomplexe

Zinn

Magnesium

Arsen

Schwefel

Stickstoff

Kohlenstoff

Lithium

Imide

Januskopf-Ligand

homobimetallische Komplexe

Komplexchemie

Polymorphie

sulfur ylides

organolithium chemistry

charge density

bonding

QTAIM

ylidic

ylenic

metal complexes

tin

magnesium

arsenic

sulfur

nitrogen

carbon

lithium

imides

janus-head ligand

homobimetallic complexes

complex chemistry

polymorphism

35.11

35.44

35.60

35.90

SP 000: Strukturchemie

SOC 250: Metallkomplexe

Chelate {Chemie: Verbindungstypen}

STJ 250: Lithium {Anorganische Chemie}

STO 270: Schwefeloxyde