Global ETD Search

81	Relation entre structure et texture de matériaux poreux et l'évaluation de leurs propriétés de piégeage du CO2 / Developing relationships between the structure and texture of porous materials and their CO2 capture properties Benoit, Virginie 19 December 2017 (has links) Les Membranes à Matrices Mixtes (MMM’s) sont des matériaux prometteurs pour la capture de CO2 en comparaison aux technologies actuelles telles que l’absorption par solvants aminés (monoéthanolamine). Les ‘Metal-Organic Frameworks’ (MOFs) sont des matériaux poreux cristallins envisagés pour être intégrés sous forme de nanoparticules aux polymères des MMM’s. Ils résultent de la combinaison de nœuds métalliques et de ligands organiques pour former des structures tridimensionnelle (3D) organisées. Ils possèdent divers avantages : des aires spécifiques et des volumes poreux élevés, des tailles de pores contrôlables, et pour certains une stabilité à l’eau. Les MOFs ont une chimie adaptable aux applications souhaitées contrairement aux adsorbants classiques tels que les charbons actifs, les zéolithes.D’une part, ce travail a eu pour objectif l’évaluation des performances de séparation du CO2 par des MOFs microporeux en vue des séparations CO2/N2 et CO2/CH4. Les interactions ‘gaz-adsorbant’ sont favorisées au sein des MOFs par : (1) une réduction de la taille de pores et du volume poreux pouvant engendrer des effets de confinements, de tamis moléculaire ou (2) par la présence de groupements de surface. En conséquence, ces paramètres peuvent contribuer à l’amélioration de la sélectivité du CO2 et ont été étudiés pour divers systèmes de MOFs microporeux. D’autre part, les paramètres texturaux (aire spécifique, volume poreux) et thermodynamiques (enthalpies d’adsorption) ont été corrélés aux quantités maximales de CO2 adsorbées au travers d’une approche quantitative de relation de structure-propriété pour établir des tendances linéaires. / Mixte Matrix Membranes (MMM’s) are promising materials for CO2 capture compared to current technologies as absorption using amines solvents (monoéthanolamine). Metal-Organic Frameworks (MOFs) are crystalline porous materials which can be integrate under nanoparticles shape to polymer phase of MMM’s. They are built from metal nods and organic ligand to yield well-defined tridimensional structure (3D). They possess various advantages: high specific surface area and pore volume, tunable pore size and some of them are stable in presence of water. MOFs have a sustainable chemistry to targeted applications unlike traditional adsorbents as activated carbons, zeolites.On the one hand, this work aimed the assessment of CO2 separation performances of microporous MOFs for CO2/N2 and CO2/CH4 gas separations. The ‘gas-adsorbent’ interactions are favored in MOFs by: (1) a decrease of pore size, pore volume which can involve confinement effects, molecular sieve effects or (2) the presence of surface groups. Therefore, these factors can contribute to the CO2 selectivity improvement and have been studied for various microporous MOFs. On the other hand, textural (specific surface area, pore volume) and thermodynamic (adsorption enthalpy) parameters have been correlated to CO2 maximum excess uptakes through a quantitative structure-property approach to establish some linear trends. Metal-Organic Frameworks Adsorption de gaz Microcalorimétrie Metal-Organic Frameworks Gas adsorption Microcalorimetry Quantitative structure-Property approach 539
82	The Chemistry of Metal Oxyhydroxides and their 3D Porous Hybrid Materials for the Capture, Transport and Degradation of Toxic Chemicals Devulapalli, Venkata Swaroopa Datta, 0000-0003-1860-9888 January 2023 (has links) Growing concerns regarding chemical weapons and toxic chemicals require the development and testing of robust materials and methods to capture and destroy these harmful chemicals. This dissertation discusses the fundamental properties (e.g., structure, stability and activity) of metal oxyhydroxide based 3-dimensional porous materials, such as metal organic frameworks (MOFs), and covalent organic frameworks (COFs), and their applications for gas capture and degradation, especially for toxic gases and chemical warfare agent simulants. We report and verify that the active sites in UiO-67 MOFs are the metal nodes (oxyhydroxides) and developed a paradigm which correlates the activities of the MOFs, the metal oxyhydroxides and their precursors. This new understanding can help researchers choose the optimum metal for the intended applications by avoiding the tedious and time-consuming procedures of MOF synthesis and purification. In addition, to characterize and understand the structures of active sites in UiO-67 MOFs, temperature programmed desorption mass spectrometry (TPD-MS) and in situ Fourier-transform infrared (FTIR) spectroscopy were performed under ultra-high vacuum (UHV) and revealed unconventional binding sites and assisted in the successful characterization of missing linker defects. Here, our research helped in identification of a new class of binding sites, via NH-π interactions, in UiO-67 MOFs will assist researchers working in the areas of gas storage/release in developing better materials. This study should facilitate the structural understanding of MOFs, their important attributes such as defects and their chemistry in the presence of toxic gases. After successful identification of active species in MOFs, with the ultimate goal of isolating andii depositing the active sites on porous carbonaceous materials, e.g., COFs, we have engineered a facile technique to synthesize robust nanoparticle-COF and evaluated the reasons for its improved catalytic properties over other materials. The discoveries and their implications discussed in this thesis address fundamental knowledge gaps and should aid the rational design of superior materials for in operando applications. / Chemistry Physical chemistry Materials science Analytical chemistry Ammonia sorption Covalent organic frameworks Metal organic frameworks Nerve agent degradation Oxyhydroxides Temperature programmed desorption
83	[en] CARBAZOLE-BASED COVALENT ORGANIC FRAMEWORKS: CONCEPTION, SYNTHESIS AND CHARACTERIZATION / [pt] COVALENT ORGANIC FRAMEWORKS BASEADOS EM CARBAZÓIS: CONCEPÇÃO, SÍNTESE E CARACTERIZAÇÃO LEONARDO SIMÕES DE ABREU CARNEIRO 07 December 2016 (has links) [pt] Materiais bidimensionais apresentam possibilidades de funcionalização que os tornam versáteis para diversas aplicações, tais como em dispositivos eletrônicos. A presença de poros nesses materiais pode trazer novas funções, como adsorção de gases, liberação controlada de fármacos e catálise. Os covalent organic frameworks (COFs) são uma nova classe de materiais orgânicos porosos cristalinos que têm recebido destaque em química reticular. O objetivo dessa dissertação é apresentar a síntese e caracterização de quatro novos COFs baseados em carbazóis, que constitui uma classe de compostos utilizada na obtenção de polímeros condutores. O bloco de montagem principal utilizado foi o 3,6-diamino-9H-carbazol e as fontes de aldeído foram triformilfloroglucinol, triformilfenol, 1,3,5-tri(4-formilfenil)benzeno e triformilbenzeno para a síntese do RIO2, RIO3, RIO5 e RIO6, respectivamente. RIO2 e RIO3 apresentaram-se sob a forma ceto enamina e imina, respectivamente, além de pouca cristalinidade e baixa área específica. Através de cálculos baseados na Teoria do Funcional da Densidade (DFT), foi verificado que esses COFs apresentam suas folhas deslocadas e rotacionadas devido às interações eletrostáticas e para minimizar os momentos de dipolo das ligações N-H dos carbazóis. RIO5 e RIO6 também se apresentaram pouco cristalinos e com áreas específicas baixas. Apesar desses resultados, esses materiais ainda podem ser aplicados em eletrônica orgânica por apresentarem estrutura química compatível com tal aplicação. / [en] Two-dimensional materials have functionalization possibilities that make them versatile for various applications such as in electronic devices. The presence of pores in these materials can give new features to them, such as gas adsorption, drug delivery and catalysis. The covalent organic frameworks (COFs) are a new class of crystalline porous organic materials that have been prominent in reticular chemistry. The purpose of this work is to present the synthesis and characterization of four new COFs based on carbazoles, which are a class of compounds used to obtain conductive polymers. The main building block used was 3,6-diamine-9H-carbazole with the aldehyde sources were triformylphloroglucinol, triformylphenol, 1,3,5-tri(4 formylphenyl)benzene and triformylbenzene to obtain RIO2, RIO3, RIO5 and RIO6, respectively. RIO2 and RIO3 are in keto-enamine and imine form, respectively, as well as have low crystallinity and low specific area. Calculus based on Density Functional Theory (DFT) found that these COFs present their sheets displaced and rotated due to electrostatic interactions and to minimize the dipole moments of the N-H bonds of carbazoles. In an attempt to avoid the absence of pores, RIO5 and RIO6 materials were synthesized, however these COFs also performed poorly crystalline and with low specific areas. Despite these results, these materials can also be applied in organic electronics by presenting chemical structure compatible with such application. [pt] POROSIDADE [pt] MATERIAL BIDIMENSIONAL [pt] TAUTOMERIA [pt] COVALENT ORGANIC FRAMEWORKS [pt] CARBAZOL [en] POROSITY [en] TWO-DIMENSIONAL MATERIAL [en] TAUTOMERISM [en] COVALENT ORGANIC FRAMEWORKS [en] CARBAZOL
84	Industrially challenging separations via adsorption in metal-organic frameworks : a computational exploration Lennox, Matthew James January 2015 (has links) In recent years, metal-organic frameworks (MOFs) have been identified as promising adsorbents in a number of industrially relevant, yet challenging, separations, including the removal of propane from propane/propylene mixtures and the separation of mixtures of xylene isomers. The highly tuneable nature of MOFs - wherein structures may be constructed from a variety of diverse building blocks – has resulted in the publication of a staggering number of frameworks incorporating a wide range of network topologies, pore shapes and pore diameters. As a result, there are a huge number of candidate adsorbents to consider for a given separation. Molecular simulation techniques allow the identification of those structural features and characteristics of a MOF which exert the greatest influence on the adsorption and separation of the compounds of interest, providing insights which can both guide the selection and accelerate the development of adsorbents for a specific application. The separation of propane/propylene mixtures via adsorption has typically focused on selective adsorption of the olefin, propylene, via specific olefin-adsorbent interactions. These propylene-selective MOFs result in processes which selectively remove the most abundant species in the process stream and are typically characterised by high heats of adsorption, resulting in large adsorption units and adsorbents which are difficult to regenerate. In this work, the capability of MOFs to selectively adsorb propane over propylene is explored, potentially allowing for the design of smaller and more energy-efficient adsorption units. By studying a range of different MOFs as well as carbon-based model pores, it was found that the low-pressure selectivity of the structure is determined by the strength of the electrostatic interaction between propylene and the framework, while the adsorptive preference at industrially-relevant pressures is dominated by the enhanced packing efficiency of propylene over propane. The confinement of C3 molecules, however, may be employed to negate this entropic advantage and guide the development of materials which selectively adsorb propane over propylene. It has recently been reported that the adsorptive preference of a MOF for one xylene isomer over another may be predicted based solely on the pore size distribution of the structure. In this work, the impact of pore size on selectivity was studied systematically in both one-dimensional model pore systems of varying geometries and analogous published MOF structures. The ability of the framework to discriminate between xylene molecules in these systems was found to be determined primarily by the different packing arrangements available to the different isomers – while small pores were found to favour the slimmest of the isomers, larger pores were found to favour the more compact ortho- isomer. Finally, the adsorption and diffusion of xylene isomers in a more complex MOF, UiO-66(Zr), was studied in depth. Simulations were able to correctly predict the previously-reported preference of the MOF for ortho-xylene (oX). The smaller volume of the oX molecule compared to the other isomers was found to be responsible both for an enhanced entropic contribution and higher guest-host interaction energies. The importance of framework flexibility in the diffusion of xylene isomers in UiO-66(Zr) was also explored, with distortion of the structure in response to interaction with adsorbed molecules found to be essential in allowing xylenes to diffuse through the pore space. 661
85	Synthesis and sorption studies of porous metal-organic hosts Batisai, Eustina 03 1900 (has links) Thesis (PhD)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: The first part of this study describes the synthesis of new porous materials from basic building blocks. Five structurally related ligands namely: N,N'-bis(3-pyridylmethyl)-naphthalene diimide (L1), N,N'-bis(4-pyridylmethyl)-naphthalene diimide (L2), N,N'-bis(4-pyridylmethyl)- pyromellitic diimide (L3), N,N'-bis(3-pyridylmethyl)-pyromellitic diimide (L4) and 2-(pyridin-4- ylmethyl)-benzene tricarboxylic anhydride (L5) were synthesised. Ligands L1 and L2 were reacted with metal nitrates and carboxylates as co-ligands in a systematic manner with a view to obtaining potentially porous 3–D coordination polymers. Ten structurally diverse coordination polymers were obtained and they were characterised by single-crystal X-ray diffraction, powder X-ray diffraction and thermogravimetric analysis. Four of these compounds absorb moderate amounts of CO2 and, in addition, show sorption selectivity towards CO2 over N2. The reaction of L3 and L4 with transition metal halides yielded two 1–D chains, while the reaction of L5 with transition metal nitrates yielded seven coordination polymers of which four are 2–D and three are 1–D. Of the 2–D structures three are isostructural. The second part of this work describes a variable pressure study of a flexible metal-organic framework [Zn2(BDC)2(BPY)] (BPY = 4,4 -bipyridine and BDC = 1,4-benzene dicarboxylic acid). [Zn2(BDC)2(BPY)] is one of the few examples of a flexible metal-organic framework that undergoes phase transformations in response to gas pressure. The high pressure sorption recorded for this metal-organic framework displays two inflection steps in the pressure range 0 to 30 bar, possibly indicating two phase transformations. The gas-loaded structures for each phase transformation were determined by means of single-crystal X-ray diffraction. High-pressure differential scanning calorimetry was also carried out on the system in order to determine accurate gate-opening pressures, as well as the energies involved with each phase transformation. The results correlate with those obtained from single-crystal X-ray diffraction and high-pressure sorption. The final section reports the mechanochemical synthesis of two Werner complexes [NiCl2(4- PhPy)4] (1), [CoCl2(4-PhPy)4] (2) and their corresponding solid solution [Ni0.5Co0.5Cl2(4-PhPy)4] (3) (PhPy = phenyl pyridine). The solid solution could only be formed by mechanochemical synthesis and not by conventional solution crystallisation methods. The solid solution exhibits sorption properties that differ from those of the pure compounds. / AFRIKAANSE OPSOMMING: Die eerste deel van hierdie studie beskryf die sintese van nuwe poreuse stowwe uit basiese boublokke. Vyf struktureel verwante ligande naamlik: N,N'-bis(3-piridielmetiel)-naftaleen diimied (L1), N,N'-bis(4-piridielmetiel)-naftaleen diimied (L2), N,N'-bis(4-piridielmetiel)- piromellitien diimied (L3), N,N'-bis(3-piridielmetiel)-piromellitien diimied (L4) en 2-(piridiel-4- ielmetiel)benseen trianhidried (L5) is gesintetiseer. Ligande L1 en L2 is gereageer met metaal nitrate en karboksielsure as mede-ligande in 'n sistematiese wyse met 'n oog op die verkryging van potensieel poreuse 3–D koördinasie polimere. Tien struktureel diverse koördinasie polimere is verkry en hulle is gekarakteriseer deur enkel-kristal X-straal-diffraksie, poeier X-straal diffraksie en termo-analise (thermal analysis). Vier van hierdie verbindings het matige hoeveelhede CO2 geabsorbeer en, bykomend, wys sorpsie selektiwiteit van CO2 oor N2. Die reaksie van L3 en L4 met oorgangsmetaalhaliede het twee 1–D kettings gevorm, terwyl die reaksie van L5 met oorgangsmetaal nitrate sewe koördinasie polimere opgelewer het, waarvan vier 2–D en drie 1–D polimere is. Van die 2–D polimere het drie vergelykbare strukture. Die tweede deel van hierdie werk beskryf 'n veranderlike druk studie van 'n buigsame metaalorganiese raamwerk [Zn2(BDC)2(BPY)] (BPY = 4,4-bipiridien en BDC = 1,4-benseen dikarboksielsuur). [Zn2(BDC)2(BPY)] is een van die min voorbeelde van 'n buigsame metaalorganiese raamwerk wat fase transformasies (phase transformations) ondergaan in respons op ‘n verandering in gas druk. Die hoë-druk sorpsie aangeteken vir hierdie metaal-organiese raamwerk vertoon twee infleksie stappe in die gebestudeerde druk gebied (0 tot 30 bar), wat moontlik op twee fase transformasies dui. Die gas-gelaaide strukture vir elke fase transformasie is bepaal deur middel van enkel-kristal X-straal-diffraksie. Hoë-druk differensiële skandeer kalorimetrie (differential scanning calorimetry) is ook uitgevoer op die stelsel ten einde dié akkurate hekopenings druk, sowel as die energie betrokke by elke fase transformasie te bepaal. Die resultate stem ooreen met dié verkry vanaf enkel-kristal X-straal diffraksie en hoë-druk sorpsie. Die finale afdeling bespreek die meganochemiese sintese van twee Werner komplekse [NiCl2(4-PhPy)4] (1) en [COCl2(4-PhPy)4] (2) en hul ooreenstemmende vaste oplossing (solid solution) [Ni0.5Co0.5Cl2(4-PhPy)4] (3). Die vaste oplossing kan slegs gevorm word deur meganochemiese sintese en nie deur konvensionele oplossing kristallisasie metodes. Die vaste oplossing vertoon sorpsie eienskappe wat verskil van dié van die suiwer verbindings. Crystal engineering Metal-organic frameworks Werner clathrates Porous materials UCTD
86	Synthesis, characterisation and adsorption properties of metal-organic frameworks and the structural response to functionalisation and temperature Mowat, John P. S. January 2012 (has links) The synthesis of a scandium aluminium methylphosphonate ScAl₃(CH₃PO₃)₆ isostructural to the aluminium methylphosphonate AlMePO-α and with permanent microporosity is reported here for the first time. Structural characterisation of three lanthanide bisphosphonate structures (I,II,III) with the light lanthanides and N,N'-piperazine bis-(methylenephosphonic acid) and its 2-methyl and 2,5-dimethyl derivatives is described. The framework of structure type I shows considerable flexibility upon dehydration with a symmetry change from C2/c, a = 23.5864(2) Å, b = 12.1186(2) Å, c = 5.6613(2) Å, β = 93.040(2)˚) in the hydrated state to P2₁/n, a = 21.8361(12) Å, b = 9.3519(4) Å, c = 5.5629(3) Å, β = 96.560(4)˚ after dehydration. This cell volume reduces by 27% on dehydration and is accompanied by a change in the conformation of the piperazine ring from chair to boat configuration. The structures of type I (hydrated and dehydrated) were refined against synchrotron powder X-ray diffraction data. Despite the reversible hydration and flexibility, the structures possess no permanent porosity. Investigation of the solvothermal chemistry of scandium carboxylates identified routes to 7 framework structures 5 of which were previously unreported in the scandium system. Lower temperature solvothermal reactions using terephthalic acid (80 - 140°C using dimethylformamide and diethylformamide) yielded two scandium terephthalates, MIL-88B(Sc) and MIL-101(Sc), identified by laboratory X-ray powder diffraction. Whereas higher temperature (160 – 220°C), reactions gave MIL-53(Sc) and Sc₂BDC₃. Further study with the tri- and tetra-carboxylate linkers, trimesic acid, 3,3',5,5'-azobenzenetetracarboxylic acid and pyromellitic acid yielded MIL-100(Sc), Sc-ABTC and Sc₄PMA₃ respectively. Structural identification of MIL-100(Sc) and Sc-ABTC was performed by means of X-ray powder diffraction analysis and of Sc₄PMA₃ by single crystal X-ray diffraction. The structure of a small pore scandium terephthalate Sc₂BDC₃ was investigated as a function of temperature and of functionalization. In situ synchrotron X-ray diffraction data, collected on a Sc₂BDC₃ in vacuo, enabled a phase change from orthorhombic Fddd to monoclinic C2/c and the associated structural effects to be observed in detail. The orthorhombic structure displayed a negative thermal expansivity of 2.4 × 10⁻⁵ K⁻¹ over the temperature range 225 – 523 K which Rietveld analysis showed to be derived from carboxylate group rotation. Motion within the framework was studied by ²H wide-line and MAS NMR on deuterated Sc₂BDC₃ indicating π flips can occur in the phenyl rings above 298 K. The effects of functionalization on the Sc₂BDC₃ framework were investigated by reactions using the 2-amino- and 2-nitroterephthalic acid and gave evidence for a strong structural effect resulting from inclusion of the functional groups. The structure of Sc₂BDC₃ and the functionalised derivatives were solved using Rietveld analysis on synchrotron X-ray powder diffraction data. Sc₂(NH₂-BDC)₃ was solved using the orthorhombic Sc₂BDC₃ framework starting model and, over the temperature range studied, stayed orthorhombic Fddd. Sc₂(NO₂-BDC)₃, was shown to be monoclinic C2/c over the same temperature range, a result of the steric effects of the bulky –NO₂ group in a small pore framework. Partial ordering of the functional groups was observed in both Sc₂(NH₂-BDC)₃ and Sc₂(NO₂-BDC)₃. The strength of interaction for the Sc₂(NH₂-BDC)₃ with CO₂ was higher than that of the parent Sc₂BDC₃ due to the strong –NH₂•••CO₂ interaction. Despite the inclusion of a relatively large –NO₂ group along the walls of a channel ~4 Å in diameter the Sc₂(NO₂-BDC)₃ still showed permanent microporosity to CO₂ (2.6 mmol g⁻¹) suggesting that there must be some motion in the -NO₂ group to allow the CO₂ molecules to diffuse through the channels. The scandium analogue of the flexible terephthalate MIL-53, a competitive phase in the synthesis of Sc₂BDC₃, was prepared and characterised by Rietveld analysis on synchrotron X-ray powder diffraction data using a combination of literature structural models and models obtained from single crystal X-ray diffraction experiments. Experimental solid state ⁴⁵Sc, ¹³C and ¹H NMR data combined with NMR calculations on the structural models produced from diffraction analysis were used to identify the hydrated (MIL-53(Sc)-H₂O), calcined (MIL-53(Sc)-CAL) and high temperature (MIL-53(Sc)-HT) structures of MIL-53(Sc). Further to this the 2-nitroterephthalate derivative, MIL-53(Sc)-NO₂, was prepared and characterised using single crystal X-ray diffraction. The adsorptive properties of the parent terephthalate and the functionalised derivative were compared and in both cases showed a breathing behaviour, exemplified by steps in the adsorption isotherms. MIL-53(Sc)-CAL was found to possess a closed pore configuration in the dehydrated state, a previously unreported structural form for the MIL-53 series, and its presence can be observed in the low pressure region of the CO₂ adsorption isotherm as a non-porous plateau. The selectivity and separation properties of two MOFs, the nickel bisphosphonate, STA-12(Ni) and the scandium carboxylate, Sc₂BDC₃ were measured using breakthrough curves on mixtures of CH₄ and CO₂. The results showed both materials to be highly selective in the adsorption of CO₂ over CH₄. Column testing using a PLOT column of STA-12(Ni) and a packed column of Sc₂BDC₃ showed promising preliminary results with STA-12(Ni) displaying effective, baseline separation on low boiling point hydrocarbon mixtures (C1 – C4) while the smaller pore channels of Sc₂BDC₃ were effective in the size selective separation of higher boiling point branched and straight-chain hydrocarbons (C5 – C7). 669
87	Synthesis and Characterization of Films and Membranes of Metal-Organic Framework (MOF) for Gas Separation Applications Shah, Miral Naresh 1987- 14 March 2013 (has links) Metal-Organic Frameworks (MOFs) are nanoporous framework materials with tunable pore size and functionality, and hence attractive for gas separation membrane applications. Zeolitic Imidazolate Frameworks (ZIFs), a subclass of MOFs, are known for their high thermal and chemical stability. ZIF-8 has demonstrated potential to kinetically separate propane/propene in powder and membrane form. ZIF-8 membranes propane-propene separation performance is superior in comparison to polymer, mixed matrix and carbon membranes. The overarching theme of my research is to address challenges that hinder fabrication of MOF membranes on a commercial scale and in a reproducible and scalable manner. 1. Current approaches, are specific to a given ZIF, a general synthesis route is not available. Use of multiple steps for surface modification or seeding causes reproducibility and scalability issues. 2. Conventional fabrication techniques are batch processes, thereby limiting their commercialization. Here we demonstrate two new approaches that can potentially address these challenges. First, we report one step in situ synthesis of ZIF-8 membranes on more commonly used porous α-alumina supports. By incorporating sodium formate in the in situ growth solution, well intergrown ZIF-8 membranes were synthesized on unmodified supports. The mechanism by which sodium formate promotes heterogeneous nucleation was investigated. Sodium formate reacts with zinc source to form zinc oxide layer, which in turn promotes heterogeneous nucleation. Sodium formate promotes heterogeneous nucleation in other ZIF systems as well, leading to ZIF-7, Zn(Im)2 (ZIF-61 analogue), ZIF-90, and SIM-1 films. Thus one step in situ growth using sodium formate provides a simplified, reproducible and potentially general route for ZIF film fabrication. One step in situ route, although advantageous; is still conventional in nature and batch process with long synthesis time. This limits commercialization, due to scalability and manufacturing cost issues. Taking advantage of coordination chemistry of MOFs and using temperature as driving force, continuous well-intergrown membranes of HKUST-1 and ZIF-8 in relatively short time (15 min) using Rapid Thermal Deposition (RTD). With minimum precursor consumption and simplified synthesis protocol, RTD provides potential for a continuous, scalable, reproducible and commercializable route for MOF membrane fabrication. RTD-prepared MOF membranes show improved separation performances, indicating improved microstructure. zeolites propylene/propane separation gas separation membranes films Metal-Organic Frameworks
88	Metal organic frameworks based microcantilever gas sensors for detection of volatile organic compounds Ellern, Ilya 20 September 2013 (has links) Metal Organic Frameworks (MOFs) are a new class of nanoporous materials with high surface area, thermal/chemical stability and a taylorable pore size. These properties make MOFs ideal for storage and gas separation applications. Piezoresistive microcantilever sensors are microfabricated devices that are highly sensitive to surface strain due to doped single crystal silicon regions. Changes in resistance generated by surface strain can be measured with a high degree of accuracy using a Wheatstone bridge and basic instrumentation. This thesis will discuss the use of piezoresistive microcantilever sensors as a transduction mechanism for detection of volatile organic compounds (VOC's) using MOF coatings. It will be shown that by coating a microcantilever with MOFs it is possible to detect low levels of different VOC's (hundreds of parts per million). Excellent sensitivity and a simple transduction mechanism make these devices low power and highly compact. Such devices would be capable of detecting a plethora of different analytes at low concentrations. Devices were engineered for maximum response and microfabricated in the cleanroom with high yield. A custom setup for testing the devices was designed and machined. A number of MOFs were selected and tested, their response was recorded and analyzed. Twelve different analytes including eleven VOC's and water were used to characterize the MOFs. Microcantilever sensors were shown to be durable, reliable and stable in long term testing despite being subjected to many different analytes. MOF coatings proved flexible, durable, stable and reversible. This work will show a promising new technology for a next generation gas sensor. Piezoresistive Microcantilever Gas sensors Metal organic frameworks Gas detectors Detectors Microelectromechanical systems
89	Polymorphs of lithium-boron imidazolates: energy landscape and hydrogen storage properties Baburin, Igor A., Assfour, Bassem, Seifert, Gotthard, Leoni, Stefano 31 March 2014 (has links) (PDF) The topological diversity of lithium-boron imidazolates LiB(imid)4 was studied by combining topological enumeration and ab initio DFT calculations. The structures based on zeolitic rho, gme and fau nets are shown to be stable and have high total hydrogen uptake (6.9–7.8 wt.%) comparable with that of MOF-177. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich. Metall-organische Gerüste MOF organic frameworks capture lithium-boron imidazolates BIF ddc:540 rvk:VA 1120
90	Development of Metal–Organic Frameworks for Catalysis : Designing Functional and Porous Crystals Carson, Fabian January 2015 (has links) Metal–organic frameworks, or MOFs, have emerged as a new class of porous materials made by linking metal and organic units. The easy preparation, structural and functional tunability, ultrahigh porosity, and enormous surface areas of MOFs have led to them becoming one of the fastest growing fields in chemistry. MOFs have potential applications in numerous areas such as clean energy, adsorption and separation processes, biomedicine, and sensing. One of the most promising areas of research with MOFs is heterogeneous catalysis. This thesis describes the design and synthesis of new, carboxylate-based MOFs for use as catalysts. These materials have been characterized using diffraction, spectroscopy, adsorption, and imaging techniques. The thesis has focused on preparing highly-stable MOFs for catalysis, using post-synthetic methods to modify the properties of these crystals, and applying a combination of characterization techniques to probe these complex materials. In the first part of this thesis, several new vanadium MOFs have been presented. The synthesis of MIL-88B(V), MIL-101(V), and MIL-47 were studied using ex situ techniques to gain insight into the synthesis–structure relationships. The properties of these materials have also been studied. In the second part, the use of MOFs as supports for metallic nanoparticles has been investigated. These materials, Pd@MIL-101–NH2(Cr) and Pd@MIL-88B–NH2(Cr), were used as catalysts for Suzuki–Miyaura and oxidation reactions, respectively. The effect of the base on the catalytic activity, crystallinity, porosity, and palladium distribution of Pd@MIL-101–NH2(Cr) was studied. In the final part, the introduction of transition-metal complexes into MOFs through different synthesis routes has been described. A ruthenium complex was grafted onto an aluminium MOF, MOF-253, and an iridium metallolinker was introduced into a zirconium MOF, UiO-68–2CH3. These materials were used as catalysts for alcohol oxidation and allylic alcohol isomerization, respectively. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: Manuscript. Paper 5: Manuscript.</p> Metal–organic frameworks heterogeneous catalysis nanoparticles metallolinkers postsynthetic modification postsynthetic exchange

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