Global ETD Search

101	Hochporöse und flexible metallorganische Gerüstverbindungen basierend auf Stickstoff-haltigen Carboxylat-Liganden Grünker, Ronny 18 February 2013 (has links) (PDF) Metallorganische Gerüstverbindungen (engl.: Metal-organic Framework, MOFs) haben sich in den letzten Jahren neben Zeolithen, Aktivkohlen und anderen als eine weitere Klasse poröser Materialien etabliert. Die Möglichkeit des individuellen Designs von Eigenschaften wie Porengröße und -geometrie, innerer Oberfläche und Porenvolumen, der Hydrophilie und Funktionalität machen diese Materialklasse zum Gegenstand der Forschung in den vielfältigsten Gebieten. Darüber hinaus besitzen sie unter porösen Materialien exklusiv die Eigenschaft der definierten strukturellen Flexibilität, welche in Kombination mit bereits genannten Eigenschaften eine weitere Vielzahl an neuen möglichen Anwendungen erahnen lässt. Die Faszination dieser strukturellen Flexibilität von MOFs sowie die Möglichkeit der Kontrolle dieser Eigenschaft sollten im Fokus der Betrachtung stehen. Zur Integration von Flexibilität in dreidimensionale Netzwerke wurde als Strategie der Einsatz von semi-flexiblen Linkermolekülen gewählt. Eine potentielle Molekülklasse für diese Art der Untersuchung stellen Triarylaminverbindungen dar, da sie trotz ihrer durchgängigen sp2-Hybridisierung über ein gewisses Maß an konformeller Flexibilität verfügen. So wurde über einen präparativ sehr guten Zugang der tetrafunktionelle H4benztb-Linker (Abbildung 1a) generiert. Durch die Kombination dieser Tetracarbonsäure mit Metall-Clustern unterschiedlicher Konnektivität resultierten acht strukturell unterschiedliche MOFs, wodurch an diesen Verbindungen Aussagen über Struktur-Eigenschafts-Beziehungen getroffen werden können. Ein weiterer Schwerpunkt dieser Arbeit war die kostengünstige Darstellung komplexer nicht-kommerzieller Liganden und daraus resultierende hochporöse MOFs sowie Untersuchungen zu deren Stabilität und Speicherkapazität für verschiedene Gase im Hochdruckbereich. Durch die Reaktion des H4benztb-Liganden mit Zinknitrat unter variierenden Synthesebedingungen konnten drei Netzwerke unterschiedlich hoher Konnektivität erhalten werden. DUT 10(Zn) (Zn2(benztb)2(H2O)2), basierend auf dem vierfach verknüpfenden dimeren Schaufelrad-Konnektor, zeigt mit einem (4,4)-Netzwerk dabei den geringsten Verzweigungsgrad. Daraus resultierend zeigt dieses Material eine sehr große strukturelle Flexibilität beim Entfernen des in den Poren vorliegenden Lösungsmittels sowie bei der Adsorption von CO2 bei -78°C bis 1 bar. Wird die Netzwerkkonnektivität durch den Einsatz eines sechsfach verknüpfenden [Zn4O]6+-Clusters erhöht, so zeigt das resultierende (4,6)-Netzwerk von DUT-13 (Zn4O(benztb)3/2) eine größere strukturelle Stabilität beim Entfernen des Lösunsgmittels sowie bei der Adsorption von Gastmolekülen im überkritischen Zustand. Für gasförmige Adsorptive zeigt das Netzwerk bei der Adsorption ein hochgradig flexibles Verhalten. Im Fall von N2 konnte über in situ-PXRD-Physisorptionsmessungen eine bislang noch nie beobachtete kristallin-amorph-kristallin-amorph-Transformation während eines Physisorptionszyklus beobachtet werden, was zeigt, dass DUT-13 über ein sog. Formgedächtnis verfügt und nach einer Amorphisierung erneut in seine ursprüngliche kristalline Form zurückkehrt. Neben der Erhöhung der Netzwerkkonnektivität wurde auch der Einfluss der partiellen Substitution des semi-flexiblen H4benztb gegen rigide Linker auf die Netzwerkflexibilität untersucht. Durch die Copolymerisationsstrategie des H4benztb mit der starren 1,3,5-Benzentribenzoesäure (H3btb) konnte DUT 25 (Zn4O(btb)2/3(benztb)) erhalten werden. Aufgrund der geringen Erhöhung der Rigidität der Verbindung zeigt dieses (3,4,6)-Netzwerk keinerlei strukturelle Flexibilität während der Aktivierung, der Adsorption von verschiedenen Gasen sowie von Gastmolekülen aus der Flüssigphase. Man erhält ein starres Material mit einer spezifischen inneren Oberfläche (SSA) von 4670 m2g-1 und einem totalen Porenvolumen (VP) von 2.22 cm3g-1. Aufbauend auf den positiven Ergebnissen der Copolymerisationsstrategie von DUT-25, wurde versucht, diese auf weitere kostengünstige Linkersysteme zur Synthese hochporöser MOF-Verbindungen auszuweiten. Durch eine effiziente und günstige Synthese einer Tricarbonsäure auf Amidbasis, 4,4´,4´´-[1,3,5-Benzentriyltris(carbonylimino)]trisbenzoesäure (H3btctb), und deren Kombination mit der linearen 4,4´-Biphenyldicarbonsäure (H2bpdc) und Zinknitrat wurde ein neues mesoporöses Koordinationspolymer DUT-32 (Zn4O(btctb)4/3(bpdc)) mit hierarchischem Porensystem erhalten. Dieses System konnte nur unter Zuhilfenahme von überkritischem CO2 in einen porösen lösungsmittelfreien Zustand überführt werden. Hierbei konnten die gravierenden Einflüsse verschiedener Parameter während der Trocknung (Lösungsmittel, Verweilzeit) auf die porösen Eigenschaften des resultierenden Materials aufgezeigt werden. Der Austausch des Reaktionslösungsmittels gegen Ethanolabs. und anschließende überkritische Trocknung führte zu einem amorphen porösen Material mit einem Typ-IV-N2-Isothermenverlauf und einer daraus berechneten spezifischen Oberfläche von 840 m2g-1, einem Mikroporen- sowie einem totalen Porenvolumen von 0.36 bzw. 2.91 cm3g-1. Erfolgt die Trocknung aus einem Lösungsmittel mit möglichst geringen Wechselwirkungen mit dem Netzwerk (Aceton, Amylacetat), so zeigt das resultierende kristalline Material nach einer CO2-Austauschzeit von drei Tagen gänzlich andere texturelle Eigenschaften mit einem Typ-I-N2-Isothermenverlauf, einer spezifischen Oberfläche von 5080 m2g-1 sowie einem totalen Porenvolumen von 2.27 cm3g-1. Wird diese Verweil- und damit die Austauschzeit im flüssigen CO2 weiter auf sieben Tage erhöht, steigt auch die Qualität/Porosität des Materials und man erhält eine Verbindung mit der bislang höchsten beschriebenen spezifischen Oberfläche (SSA = 7192 m2g-1), extrem hohem spezifischen Porenvolumen (VP = 3.16 cm3g-1) und hervorragenden Eigenschaften für die Gasspeicherung. metallorganische Gerüstverbindung Gasspeicherung Solvatochromie Sensorik Flexibilität mesoporös metal-organic framework gas storage solvatochroism sensoric flexibility mesoporous ddc:540 rvk:VH 9707
102	Pendant Functional Groups in Metal-Organic Frameworks - Effects on Crystal Structure, Stability, and Gas Sorption Properties Makal, Trevor Arnold 03 October 2013 (has links) The primary goal of this research concerns the synthesis and characterization of metal-organic frameworks (MOFs) grafted with pendant alkyl substituents to enhance stability and gas sorption properties for use in clean-energy related technologies. Initially, the focus of this work was on the synthesis and comparison of two isostructural MOFs built upon octahedral secondary building blocks; one with no alkyl substituents, and its dimethyl-substituted counterpart. The dimethyl-substituents are observed to enhance the stability of the framework, resulting in high Langmuir surface area (4859 m2 g-1) and hydrogen uptake capacity at 77 K and 1 bar (2.6 wt%). In the second section, the length of pendant alkoxy substituents in semi-flexible MOFs was evaluated through the synthesis and characterization of two isostructural MOFs, one with dimethoxy (PCN-38) and one with diethoxy pendant groups (PCN-39). While PCN-38 exhibited moderate surface area and hydrogen uptake capacities, PCN-39 underwent structural change upon activation leading to a redistribution of pore sizes and selective adsorption of hydrogen over larger gases. This structural transformation is believed to originate from optimal space filling of the pendant groups. In the third section, a series of NbO-type MOFs were synthesized with dimethoxy, diethoxy, dipropoxy, and dihexyloxy substituents and the relationship between chain length and framework stability identified. Increasing chain length was observed to increase moisture stability of the MOFs, resulting in a superhydrophobic material in the case of the dihexyloxy derivative. Thermal stability, however, decreased with increasing chain length, as evidenced from in situ synchrotron powder X-ray diffraction measurements (PXRD). This is in contrast to data obtained from thermogravimetric analysis and shows that the standard use of thermogravimetric analysis, which measures combustion temperatures, may not always provide an accurate description of the thermal stability of MOFs. The role of pendant groups in gas adsorption processes was evaluated through identification of side chains and guest species in the pores of MOFs through in situ synchrotron PXRD measurements. In summary, three separate isostructural series of MOFs with various pendant groups have been discussed in this dissertation, with the roles of those pendant groups toward crystal structure, stability, and gas sorption properties analyzed. metal-organic framework MOF porous materials gas adsorption functional materials gas storage coordination polymer metal-organic material
103	Metal Organic Frameworks (MOFs) and Porous Organic Polymers (POPs) for Heterogeneous Asymmetric Catalysis Ji, Youngran 01 January 2015 (has links) The administration of enantiopure drugs brings advantages such as improved efficacy, more predictable pharmacokinetics and reduced toxicity from the point of view of the pharmaceutical area.[1] For this reason, a tremendous amount of supply and demand for enantiomeric pure compounds has been shown not only in market, but industry and academia.[2-4] According to the industry publication Genetic Engineering and Biotechnology News (GEN) in 2014, 22 billion dollars were accounted for enantiopure form of drugs such as Sovaldi® (Sofosbuvir), Crestor® (Rosuvastatin), and Advair® (fluticasone/salmeterol). The fact that one enantiomer can be pharmacologically effective whereas the other enantiomer can be inactive or display non-desirable activity, chiral resolution and asymmetric synthesis research has broken out in recent years to obtain one desired stereoisomer. Enormous amounts of well-organized and rationalized research results for higher enantiomeric selectivity and efficiency has been reported with diverse chiral ligands and transition metals in academia.[5-10] However novelty-driven results from academic area does not meet the requirement in industry field for the practical issue, especially tedious separation process that require high cost and effort. In addition, methodologies developed with privileged chiral ligands and transition metal complexes leave a concern like undesired residue of trace amount of toxic metals in the products. In this dissertation, two types of heterogeneous asymmetric catalyst were investigated to find the alternative that accommodates industrial requirement to obtain enantiomeric pure compounds and novelty-driven academic demands. Firstly, constructions of rationally designed metal organic frameworks (MOFs) using chiral BINOL-derived phosphoric acid ligands were achieved. Overall, catalytic reactions with ocMOFs showed lower enatioselectivity than their homogeneous counterparts, but one of the MOFs, ocMOF-1, was found to exhibit improved enantioselectivity than its homogeneous counterpart in the context of transfer hydrogenation reaction of benzoxazine. Lower enatioselectivity with ocMOFs was rationalized by the chiral environment change by the formation of frameworks in a computational study. In addition, self-supported heterogenization of chiral BINOL-phosphoric acid was achieved by the Yamamoto coupling reaction, and by using catalytically active ocPOP-1 having nanoscopic channels, enantioselectivity was obtained up to 48% in transfer hydrogenation of N-PMP ketimine. Although extension of substituent groups at 3, 3' positions was expected to bring enhanced steric hindrance and to influence to enantioselectivity positively, lack of spatially well-defined interactions induced by this chiral environment change might have lowered the enantiomeric selectivity of the catalytic reaction using ocPOP-1 than its counterpart. metal organic framework metal organic material porous organic polymer BINOL asymmetric heterogeneous catalysis Chemistry Medicinal and Pharmaceutical Chemistry
104	Synthesis, crystallographic and magnetic studies of lanthanide-based molecular edifices / Synthèse, études cristallographiques et magnétiques d'édifices moléculaires à base de lanthanides Huang, Gang 31 March 2017 (has links) Les molécules-aimants ou Single–Molécule Magnets (SMM) ont attiré une attention croissante au cours des dernières années en raison de leur potentiel attrayant en tant que dispositifs de stockage magnétique à haute densité. Beaucoup d'efforts ont été faits pour améliorer la performance magnétique de ces molécules à l’aide des techniques de chimie de coordination.Dans cette thèse, le travail est organisé en deux parties principales. La première partie est constituée des chapitres 2 et 3 qui se concentrent principalement sur les familles Lanthanide-radicaux zéro- et mono-dimensionnelles. La deuxième partie contient les chapitres 4 et 5, ou des ligands diamagnétiques sont utilisés afin concevoir des matériaux multifonctionnels.Dans la première partie, neuf radicaux TEMPO-R (R représente le substituant) sont utilisés. Leur structure cristalline, ainsi que leurs propriétés magnétiques ont été caractérisées. Dans le chapitre 2, quatre radicaux (TEMPO-OCH3, TEMPO-NH2 TEMPO-Acetamido et TEMPO-OCH2CCH) sont utilisés pour synthétiser des complexes zéro-dimensionnels, dont trois présentent des propriétés de SMM. Dans le cas particulier de TEMPO-OCH3, un très rare comportement de SMM avec lanthanides légers est observé (CeIII, PrIII et NdIII). La première SMM à base de PrIII est ainsi reportée. Dans le chapitre 3, l'objectif est de concevoir des SMM organisés mono-dimensionnellement dans l’empilement cristallin. Cinq autres radicaux sont utilisés: TEMPO-Méthacrylate, TEMPO-OCOPh, TEMPO-oxo, TEMPO-OH et TEMPO-CN. Parmi toutes les chaînes obtenues, [Pr(hfac)3(H2O)(TEMPO-OH)]n (17), [Dy(hfac)3-TEMPO-OH)]n (18) et [Tb(hfac)TEMPO-CN)]n (22) sont identifiés comme SMM. 22 présente la relaxation magnétique la plus lente parmi tous les SMM 4f-2p obtenues dans cette thèse, avec une d'hystérèse magnétique à basse température. Son analogue à base GdIII (23) présente une des plus grandes valeurs d'échange dans les composés de Gd-2p. Enfin un très rare exemple de réseau bidimensionnel 4f-2p de formule [(Ce(hfac)3)3(Oxo-TEMPO)4]n (15) est obtenu. Dans la deuxième partie, une chaine de dimère est obtenue par réaction d'un ligand carboxylique photo-commutable avec des sels d’ions LnIII. La photo-sensibilité du ligand sous irradiation UV a été testée et des mesures magnétiques en solution ont été entreprises. En outre, un composé de type Metal-Organic-Framework (MOF) présentant un comportement de SMM de {[Dy2(o-PDA)3(H2O)2]2H2O}n (28) a été conçu et caractérisé. Une interaction ferromagnétique Ln-Ln a été observée dans ce MOF-SMM et le dopage diamagnétique démontre que, contrairement à ce qui est observé sur [Ln(AZO)3(DMSO)(H2O)]2•4DMSO, cette interaction favorise le comportement de SMM. / Single-molecule-magnet (SMM) has attracted increasing attention in recent years due to their appealing potential for high-density storage devices. Much effort has been made to improve the magnetic performance through flexible coordination chemistry strategy.In this thesis, the work is organized in two main parts. The first part is constituted of chapter 2 and chapter 3, primarily focus on the Ln-Radical families aiming at designing zero-dimensional and one-dimensional single-molecule-magnet (SMM). The second part contains chapter 4 and chapter 5, in which the ligands are replaced by diamagnetic ones for the purpose of designing the multifunctional materials.In the first part, nine TEMPO-R (R represents the substituent) radicals are employed to construct zero-dimensional and one-dimensional complexes. These kinds of compounds were prepared by reactions in the dichloromethane/n-heptane co-solvents between the precursor [Ln(hfac)3(H2O)2] and TEMPO radicals. Subsequently their molecular structure as well as magnetic properties have been characterized and described. In chapter 2, four radicals (TEMPO-OCH3, TEMPO-NH2 TEMPO-Acetamido and TEMPO-OCH2CCH) are used to synthesize monometallic or dimetallic complexes, among which three are successful to construct the SMM. For the special case of TEMPO-OCH3 a rare light lanthanide ions (CeIII, PrIII and NdIII) SMM behavior is reported. The PrIII derivative is the first PrIII-based SMM ever reported. In chapter 3, the target is to design SMM in one dimension by using another five radicals: TEMPO-Methacrylate, TEMPO-OCOPh, TEMPO-oxo, TEMPO-OH and TEMPO-CN. Among all the chains, [Pr(hfac)3(H2O)(TEMPO-OH)]n (17), [Dy(hfac)3-TEMPO-OH)]n (18) and [Tb(hfac)3(TEMPO-CN)]n (22) are identified as chains of SMM. 22 exhibits the slowest magnetic relaxation among all the 4f-2p SMMs obtained in this thesis, with a small opening of magnetic hysteresis. Its analogue of [Gd(hfac)3(TEMPO-CN)]n (23) even exhibits one of the largest exchange values in Gd-2p compounds. Last a very rare example of bidimensional 4f-2p network of formula [(Ce(hfac)3)3(Oxo-TEMPO)4]n (15) is obtained.In chapter 4, the salt of a photo-switchable carboxylic ligand was reacted with LnIII ions to afford a chain-like arrangement of dinuclear complexes of formula [Ln(AZO)3(DMSO)(H2O)]2•4DMSO. Photo-sensitivity of the ligand under the irradiation of UV has been tested together with magnetic measurements in solution. In chapter 5, a Metal-Organic-Framework (MOF) (28) has been designed and characterized. Ln-Ln ferromagnetic interaction has been observed and diamagnetic doping highlight that, contrary to what observed on [Ln(AZO)3(DMSO)(H2O)]2•4DMSO, this interaction promote SMM behavior in a so-called MOF-SMM. Couplage d'échange Ligand photoactif Lanthanide Single-Molecule-Magnet Molecular magnetism Radicals Exchange couplings Exchange couplings Metal organic framework 540
105	Studies on the Dimensional Extension of Halogen-Bridged Transition-Metal Chain: Nanotube and Three-Dimensional Network / ハロゲン架橋遷移金属鎖の次元拡張に関する研究：ナノチューブと三次元ネットワーク Liang, Hao 25 September 2023 (has links) 京都大学 / 新制・課程博士 / 博士(理学) / 甲第24872号 / 理博第4982号 / 新制\|\|理\|\|1711(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)教授北川宏, 教授有賀哲也, 教授堀毛悟史 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM Metal-organic framework Halogen-Bridged Transition-Metal Chain Dimensional extension Nanotube 3D network Electronic state Proton conduction 400
106	The Dielectric Response of Mobile Counter-ions in Charged Metal-Organic Frameworks Godfrey, Aaron P. 09 August 2010 (has links) No description available. Physics metal organic framework polymer coordination network dielectric response dielectrics frameworks mofs pcns glass glassy dynamics glass transitions phase transitions
107	Studies on the Synthesis and Structural Characterization of Magnesium Carboxylates with Flexible and Rigid Organic Acid Linkers Siddiqui, Tausif January 2013 (has links) No description available. Chemistry Inorganic Chemistry Materials Science Metal organic framework magnesium carboxylates flexible organic acid linkers rigid organic acid linkers
108	Development of Cellulose-Titanium dioxide-Porphyrin Nanocomposite Films with High-barrier, UV-blocking, and Visible Light-Responsive Antimicrobial Features Lovely, Belladini 03 June 2024 (has links) The packaging does not serve as a mere containment but also can be designed to play a key role in preserving the product from quality-deteriorating factors, including oxygen, light irradiation, and foodborne pathogenic microorganisms (e.g., Escherichia coli). There has been a growing interest in employing ultra-porous metal-organic frameworks (MOF) with visible light-responsive antibacterial mechanisms to generate reactive oxygen species (ROS) that can eliminate bacteria via an oxidative burst. MOF is made of inorganic metal ions/nodes/clusters/secondary building units linked by organic bridge ligands, where titanium dioxide (TiO2) and tetrakis(4-carboxyphenyl)porphyrin) (TCPP) were selected for these components, respectively. TiO2 is an exceptional UV-A/B/C-blocker; meanwhile, TCPP dye performs a remarkable photocatalytic ability even under visible light, on top of its macro-heterocyclic structure that is ideal as a MOF linker. Both have good compatibility but suffer from the notorious tendency to self-quench/aggregate. The incorporation of MOF-based conjugates into a polymeric matrix, like cellulose, is among the proven-successful solutions. Cellulose is the Earth's most abundant and naturally biodegradable, and cellulose nanofibril (CNF) was particularly chosen for its high specific surface area and surface activity. However, a straightforward, cheap, and environmentally friendly approach of multicycle homogenization (0-25 passes) was conducted to solve neat cellulose's challenge of natural hydrophilicity, where low pressure (<10 MPa) was applied to prevent the common over-shearing effect. The antibacterial efficacy of CNF films functionalized with TiO2-TCPP conjugate on inhibiting E. coli growth was analyzed with and without light of different intensities (3000 and 6000 lux). The positive impacts of CNFs' promoted fibrillation and subsequent inter/intra-molecular hydrogen bonding post-homogenization were evidenced in an array of functional properties, i.e., crystallinity, TiO2-TCPP conjugate dispersion, surface smoothness, mechanical properties, thermal stability, hydrophobicity, oxygen barrier (comparable to ethylene-vinyl alcohol (EVOH), a commercial high-barrier polymer), and 100%-antibacterial rate (under 6000 lux after 72 hours). Varying optimum cycles of homogenization demonstrated the prospect of the proposed homogenization approach in preparing CNF with diverse processability and applicability. These findings also exhibited a promising potential for a myriad of high-barrier, UV-blocking, and/or visible light-responsive antibacterial film applications, including food packaging and biomedical. / Doctor of Philosophy / Packaging is useful not only as a container but can also be designed to help prevent products from being spoiled due to various reasons such as oxidation, light, and bacterial contamination. Researchers have discovered the promising antibacterial feature of the metal-organic framework (MOF). Packaging made with MOF technology can harness light and oxygen in the environment to produce a special form of oxygen called reactive oxygen species (ROS) that can kill unwanted bacteria. MOF is an extremely porous sponge-like material made of two ingredients: an inorganic metal cluster and an organic linker; in this study, titanium dioxide (TiO2) and a porphyrin called TCPP were selected, respectively. TiO2 is an excellent ultraviolet blocker, while TCPP has a unique, ring-like geometry that is ideal for use as a linker and an antimicrobial feature that works well under the visible light spectrum. The pair are compatible but still suffer from MOF's notorious challenge, where it tends to clump together because of its tiny size. To resolve this problem, TiO2-TCPP MOF can be deposited evenly in a cast made of polymer. Cellulose has been proven to work effectively as a polymeric cast; moreover, it is natural, biodegradable, and in abundant supply. A type of nanosized cellulose—cellulose nanofibril (CNF)—was specifically chosen because its high surface area and activity are useful when blended with other materials. However, cellulose is naturally a poor water-repellant that is not ideal for packaging applications. As a solution, cellulose can be treated with a homogenization technique by passing the material through a very narrow hole under high pressure. Homogenization can be problematic as it possibly damages the cellulose's structure, and its high pressure can also be expensive and energy consuming. Therefore, low pressure with multiple cycles was applied in this work. CNF-TiO2-TCPP films were tested for their ability to slow down E. coli bacteria growth with and without light of varying brightness to compare its light-sensitive antimicrobial feature. Homogenization was found helpful in producing higher-quality CNF, which improved several of the film's final characteristics, including an even material dispersion, structural order, smoothness, strength, heat resistance, and water repellency. Most importantly, it produced films with oxygen barrier ability comparable to commercial high-barrier plastics and completely eliminated bacteria after 72 hours. The optimum number of homogenization cycles was found to be dependent on the desired characteristics and application. Overall, these findings carry a promising potential for a variety of applications, including food packaging and the biomedical field. Cellulose nanofibrils (CNF) Titanium dioxide (TiO2) Photosensitive antibacterial agents Homogenization cycles/passes
109	New nitric oxide releasing materials McKinlay, Alistair C. January 2010 (has links) The aim of this thesis was to examine the ability of metal organic frameworks (MOFs) to store and controllably release biologically significant amounts of nitric oxide (NO). Initial work involved the synthesis of a series of isostructural MOFs, known as M-CPO-27, which display coordinatively unsaturated metal sites (CUSs) when fully activated (guest solvent molecules both coordinated and uncoordinated to the metal atom are removed). Two of these frameworks (Ni and Co CPO-27) displayed exceptional performance over the entire cycle of activation, storage and delivery showing the largest storage and release of NO of any known porous material (up to 7 mmolg⁻¹). These frameworks would therefore be considered for initial research into the formulation of MOFs, for possible use in medical applications. It was shown that they still release large amounts of NO even when placed inside porous paper bags, creams or hydrocolloids. The other versions of M-CPO-27 also displayed significant adsorption of NO however they show poor total NO release. It was also shown that it is possible to synthesise both Ni and Co CPO-27 using microwave synthesis without any detrimental effect to the porous structure. Several iron-based MOFs were also investigated for NO storage and release. The results showed that Fe MIL-88 based structures adsorb good amounts of NO but only release a small amount of the irreversibly adsorbed NO. Two successfully amine grafted giant pore MOFs were then investigated to attempt to improve the NO adsorption and release. This result was not observed however, due to the poor total amine grafting coverage and pore blockage resulting from the amines. In-situ IR studies reveal that when exposed to NO, activated Fe MIL-100 forms a chemical bond with the NO. The studies also displayed that when water is then allowed to attempt to replace the NO that only a small amount of NO is actually released, the majority of the NO either remains chemically bonded to the Fe atom or forms N₂O in conjunction with a Fe-OH group. Other MOFs were also successfully synthesised and characterised for NO storage and release. Both Ni succinate and Ni STA-12 display good adsorption and excellent release of NO. This indicates that Ni based MOFs show the best results for NO adsorption and release. In the conclusion of the thesis I am able to categorise the NO release ability of MOFs based on composition and formulate a theory as to why this happens. 547.05
110	Application of a chiral metal–organic framework in enantioselective separation Padmanaban, Mohan, Müller, Philipp, Lieder, Christian, Gedrich, Kristina, Grünker, Ronny, Bon, Volodymyr, Senkovska, Irena, Baumgärtner, Sandra, Opelt, Sabine, Paasch, Silvia, Brunner, Eike, Glorius, Frank, Klemm, Elias, Kaskel, Stefan 31 March 2014 (has links) (PDF) A modular approach for the synthesis of highly ordered porous and chiral auxiliary (Evans auxiliary) decorated metal–organic frameworks is developed. Our synthesis strategy, which uses known porous structures as model materials for incorporation of chirality via linker modification, can provide access to a wide range of porous materials suitable for enantioselective separation and catalysis. Chiral analogues of UMCM-1 have been synthesized and investigated for the enantioseparation of chiral compounds in the liquid phase and first promising results are reported. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich. selektive Adsorption heterogene Katalyse Xylole-Isomere MOF Metall-organische Gerüste selective adsorption heterogeneous catalysis xylene isomers mil-47 mofs Metal-Organic Framework ddc:540 rvk:VA 1120

Search results