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Metal organic frameworks based microcantilever gas sensors for detection of volatile organic compoundsEllern, 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.
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La chimie organométallique de surface appliquée aux structures organométalliques poreuses (MOF) : synthèses, caractérisations, et leurs applications en catalyseLarabi, Cherif 13 January 2011 (has links) (PDF)
Les structures organométalliques poreuses (Metal Organic Framework, MOF) sont une nouvelle classe de matériaux, composées d'ions métalliques ou de clusters liés à des ligands organiques ou des complexes organométalliques dans des réseaux cristallins 1D, 2D ou 3D. Au cours de cette thèse la possibilité de construire de nouveaux MOF a été illustrée par le développement de matériaux MOF à base d'imidazolium, précurseur important pour la synthèse de catalyseurs. En outre, ce travail démontre l'utilité de la modification post-synthèse des MOFs par chimie organométallique de surface à visée catalytique : i) un MOF connu, UiO-66, avec des pores relativement petits a été fonctionnalisé avec un groupement amino et ses capacités d'adsorption de gaz ont été étudiées. ii) la synthèse de MOF a structure poreuse, CPO-27, MOF a été optimisée et utilisée comme précurseur pour produire un catalyseur d'hydrodésulfuration après l'introduction d'espèces actives, via la chimie organométallique de surface, dont les performances catalytiques ont été évaluées.
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Development of Metal–Organic Frameworks for Catalysis : Designing Functional and Porous CrystalsCarson, 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>
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Metal-Organic Hybrid Nanocomposites For Energy Harvesting ApplicationsAbeywickrama, Thulitha Madawa 01 October 2016 (has links)
Various synthetic methods have been developed to produce metal nanostructures including copper and iron nanostructures. Modification of nanoparticle surface to enhance their characteristic properties through surface functionalization with organic ligands ranging from small molecules to polymeric materials including organic semiconducting polymers is a key interest in nanoscience. However, most of the synthetic methods developed in the past depend widely on non-aqueous solvents, toxic reducing agents, and high temperature and high-pressure conditions. Therefore, to produce metal nanostructures and their nanocomposites with a simpler and greener method is indeed necessary and desirable for their nano-scale applications. Hence the objective of this thesis work is to develop an environmentally friendly synthesis method to make welldefined copper and iron nanostructures on a large-scale. The size and shape-dependent optical properties, solid-state crystal packing, and morphologies of nanostructures have been evaluated with respect to various experimental parameters.
Nanostructures of copper and iron were prepared by developing an aqueous phase chemical reduction method from copper(II) chloride and Fe(III) chloride hexahydrate upon reduction using a mild reducing agent, sodium borohydride, under an inert atmosphere at room temperature. Well-defined copper nanocubes with an average edge length of 100±35 nm and iron nanochains with an average chain length up to 1.70 μm were prepared. The effect of the molar ratios of each precursor to the reducing agent, reaction time, and addition rate of the reducing agent were also evaluated in order to develop an optimized synthesis method for synthesis of these nanostructures. UV-visible spectral traces and X-ray powder diffraction traces were obtained to confirm the successful preparation of both nanostructrues. The synthesis method developed here was further modified to make poly(3-hexylthiophene) coated iron nanocomposites by surface functionalization with poly(3-hexylthiophene) carboxylate anion. Since these nanostructrues and nanocomposites have the ability to disperse in both aqueous-based solvents and organic solvents, the synthesis method provides opportunities to apply these metal nanostructures on a variety of surfaces using solution based fabrication techniques such as spin coating and spray coating methods.
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Structure-property relationships in framework materials : anomalous mechanics by designCollings, Ines Emily January 2014 (has links)
Framework materials that contain molecular bridging ligands between metal nodes—as seen in coordination polymers—not only give rise to enhanced structural diversity, but also to a range of useful and unusual mechanical properties. This thesis demonstrates the general structure–property relationships that are developed for coordination polymers in order to enable prediction and design of their mechanical properties, and hence structural flexibility. Variable-temperature and -pressure diffraction experiments are employed for the determination of their mechanical properties, namely by calculating thermal expansion and compressibility coefficients. The anomalous and varied mechanical responses observed are rationalised by the important structural features, or the so-called mechanical building units (XBUs), of the coordination polymers. The XBUs are considered within the setting of framework topology, geometry, and composition in order to establish general design principles for targeting different degrees of flexibility within coordination polymers. The XBUs are identified first in silver(I) 2-methylimidazolate, Ag(mim), a framework which is comprised of structural motifs of varying strength, namely argentophilic interactions, hinge points and metal–ligand bonding. The anomalous mechanical responses in Ag(mim) are shown to be rationalised entirely by the XBUs present in the structure. The XBU abstraction is then applied to a range of other coordination polymers and shown to correspond directly with the anomalous responses known in these materials. The metal–ligand–metal linker XBU is investigated further in both cadmium imidazolate, Cd(im)<sub>2</sub>, and zinc cyanide, Zn(CN)<sub>2</sub>. Here, the linker chemistries are completely different between the two frameworks, but the diamondoid arrangement of the linkers, and thus the topology, is the same. The structural responses of the two frameworks are examined to unravel the extent of topology- and chemistry-driven mechanics. It is found that the topology dominates the atomic displacements of both frameworks, indicating the existence of common soft-mode dynamics which are likely to extend to other coordination polymers with the same topology. The three-dimensional framework-hinging XBUs in zinc isonicotinate, Zn(ISN)<sub>2</sub>, and indium deuterium terephthalate, InD(BDC)<sub>2</sub>, are considered next. These frameworks have the same topology but contrasting framework geometries, evident from the differing c/a-lattice parameter ratios. In this case, a geometric formalism is derived which can predict the direction of framework mechanical anisotropy in Zn(ISN)<sub>2</sub> and InD(BDC)<sub>2</sub> and other uniaxial coordination polymers. Finally, a family of ABX<sub>3</sub>-type transition metal(II) formates are investigated, where both the B-site and A-site cations are varied. The chemical modifications give rise to variations in B- or A-site cation sizes, which are found to correlate with the magnitude of mechanical responses. These structure–mechanical property relationships—based upon framework topology, geometry and composition—are presented in separate chapters, and in each case generalised so that they can be applied to a range of coordination polymers. Hence the design principles determined here can provide the materials science community with an intuition on the type and magnitude of responses possible in these materials under different external stimuli.
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Synthesis and characterization of crystalline microporous materials : investigation of new synthetic routesTian, Yuyang January 2014 (has links)
Conventionally, crystalline microporous materials such as zeolites and metal-organic frameworks (MOFs) are synthesized through the hydrothermal route or the trial-and-error approach. Other synthetic strategies may lead to the synthesis of microporous materials with new architectures or interesting properties. The general aim of this thesis is to investigate some new synthetic routes towards crystalline microporous materials. A top-down and post-synthesis method is reported in Chapter 4. Some zeolites are built up by layers and double-4-ring pillars. Germanium is preferentially located in the double-4-ring sites of a zeolite framework and is hydrolytically unstable. The idea of the top-down method is to disassemble these zeolites to the layer structures by dissolving the Ge-containing pillars and reassemble them to a new framework. This method is applied to the germanosilicate IWW and ITH zeolites for the first time. The effects of framework chemical compositions, Ge distributions and disassembling conditions on the top-down treatment process are investigated. The products obtained from the top-down treatment are characterised. An ionic liquid assisted strategy for the synthesis of zeolites is described in Chapter 5. The ionic liquid assisted strategy is a solvent free reaction. The raw materials are transformed to zeolites through a solid state reaction. The ionic liquids are first used as structure-directing agents (SDAs) in this solvent free reaction to replace the expensive quaternary ammonium hydroxide. A TON zeolite is synthesized using 1-ethyl-3-methylimidazolium bromide as the SDA. Moreover, the ionic liquid assisted strategy is considered as a “green chemistry” synthetic route due to the high yield of the zeolites and the minor production of waste water. Many aluminophosphates have been successfully synthesized through ionothermal routes. Most of them are synthesized using 1-alkyl-3-methylimidazolium based ionic liquids. A new ionic liquid, 1-(2-hydroxyl-ethyl)-3-methylimidazolium chloride ([HOEmim]Cl), is prepared and used for the ionothermal synthesis of aluminophosphate materials. A zeolite analogue with the CHA framework has been synthesized. At high synthetic temperatures, the products are large single crystals. The structures of the framework and the SDA are investigated by single crystal diffraction and other characterisation methods. Flexible MOF materials are usually synthesized by a trial-and-error approach. Recently a flexible MOF compound was synthesized using 5-sulfoisophthalic acid (SIP) as the ligand. It was proposed the sulfonate is weakly coordinated to the metal, which brings flexibility to the compound, and the carboxylate groups keep the framework intact. 2-sulfoterephthalic acid (STP) which also contains one sulfonate group and two carboxylate groups is believed to be an alternative ligand for the targeted synthesis of flexible MOFs. In Chapter 7, a MOF compound is synthesized using STP and 4, 4'-bipyridine (Bpy) as ligands to validate the proposed strategy can be generalized. Variable temperature single crystal diffraction analysis solves the structure and reveals a reversible structure transformation upon dehydration and rehydration.
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Synthesis of Zeolitic Imidazolate Framework-8-Based Nanocomposites and ApplicationsZhuang, Jia January 2015 (has links)
Thesis advisor: Chia-Kuang Tsung / Thesis advisor: Eranthie Weerapana / Metal-Organic Frameworks (MOFs) are crystalline porous materials constructed of metal ions and organic linkers, and have been widely utilized in gas storage, sensing, and chromatographic separation. The combination of MOF nanoparticles with other materials will broaden the utilization of MOF materials to a great extent. Several approaches for creating composites with the MOF, Zeolitic Imidazolate Framework-8 (ZIF-8), have been developed: dye and model drug molecules were encapsulated in ZIF-8 pores for potential drug delivery; mesoporous silica monolayer was epitaxially grown on the ZIF-8 surface for structural stability enhancement and hollow structure formation; UiO-66, another MOF subclass, was hierarchically encased inside ZIF-8 for double-phase gas separation and heterogeneous catalysis. By exploring the versatile ZIF-8 platform, these nanocomposites could have great applications in fields such as heterogeneous catalysis and drug delivery. / Thesis (MS) — Boston College, 2015. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.
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S?ntese e caracteriza??o de Metal-Organic Framework (MOF) para uso na adsor??o de CO2 / Synthesis and characterization of Metal-Organic Framework (MOF) for use in CO2 adsorptionPhilippi, Mar?lia 31 August 2017 (has links)
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Previous issue date: 2017-08-31 / Coordena??o de Aperfei?oamento de Pessoal de N?vel Superior - CAPES / Growing concern about global warming and reducing greenhouse gas emissions in the atmosphere has driven the development of technological options to reduce the negative impacts of human activities, and CO2 capture and storage is one of them. Solid adsorbent materials are being used with the aim of adsorbing polluting gases. Metal-Organic Frameworks (MOFs) are a class of porous materials of great potential for adsorption of greenhouse gases, formed by the connection of metallic ions and organic binders. In this context, the objective of this work is to synthesize the MOF of type NH2-MIL-53(Al), to characterize and evaluate its use in the adsorption of carbon dioxide. For synthesis of the MOF, a hydrothermal process was used in a PFA closed reactor (155 ?C) with subsequent washes and resuspensions, obtaining an average mass yield of 90%. The obtained MOF was characterized with the use of the techniques such as SEM-FEG-EDS, elemental analysis, FAAS, XRF, FTIR, TGA, XRD/Refinement by the Rietveld Method and MAS-NMR, exhibiting characteristics of the structure NH2-MIL-53(Al). For the adsorption and desorption tests of CO2 the synthesized material was used as a powder in a fixed bed system. The synthesized MOF presented CO2 adsorption capacity of 0.13 mmol g-1 and SBET of 27 m2 g-1, lower than that reported in the literature, which were attributed to the presence of occluded binder in the pores of the material. The calculated average cost for the synthesis of the MOF in the laboratory was 34% of the value of the non-functionalized commercial standard available in the market. The residual solvent purification process from the MOF synthesis proved to be satisfactory, completely removing the DMF and with a residual contribution of methanol of only 0.00008%. / A crescente preocupa??o com o aquecimento global e com a redu??o das emiss?es de gases de efeito estufa na atmosfera tem impulsionado o desenvolvimento de op??es tecnol?gicas para redu??o dos impactos negativos das atividades humanas e, a captura e armazenamento de CO2 ? uma delas. Materiais s?lidos adsorventes est?o sendo utilizados com o objetivo de adsorver gases poluentes. Os Metal-Organic Frameworks (MOFs) s?o uma classe de materiais porosos de grande potencial para adsor??o de gases de efeito estufa, formados pela conex?o de ?ons met?licos e ligantes org?nicos. Neste contexto, o objetivo deste trabalho ? sintetizar o MOF do tipo NH2-MIL-53(Al), caracterizar e avaliar seu uso na adsor??o de di?xido de carbono. Para s?ntese do MOF foi utilizado processo hidrot?rmico em reator fechado de PFA (155 ?C) com posteriores lavagens e resuspens?es, obtendo um rendimento m?ssico m?dio de 90%. O MOF obtido foi caracterizado com o uso das t?cnicas como MEV-FEG-EDS, an?lise elementar, FAAS, FRX, FTIR, TGA, DRX/Refinamento pelo M?todo Rietveld e MAS-RMN, apresentando caracter?sticas da estrutura NH2-MIL-53(Al). Para os testes de adsor??o e dessor??o de CO2 o material sintetizado foi utilizado sob a forma de p? em sistema de leito fixo. O MOF sintetizado apresentou capacidade de adsor??o de CO2 de 0,13 mmol g-1 e SBET de 27 m2 g-1, inferiores ao reportado pela literatura, e que foram atribu?dos a presen?a de ligante oclu?do nos poros do material. O custo m?dio calculado para s?ntese do MOF em laborat?rio foi de 34% do valor do padr?o comercial n?o funcionalizado dispon?vel no mercado. O processo de purifica??o do solvente residual da s?ntese do MOF demonstrou ser satisfat?rio, removendo completamente o DMF e com uma contribui??o residual de metanol de apenas 0,00008%.
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Metal-organic chemical vapor deposition growth and nitrogen doping of ZnO thin films. / CUHK electronic theses & dissertations collectionJanuary 2008 (has links)
Electrical and optical properties of the (N,Ga)-doped ZnO films have been studied. Three growth regions were identified to obtain ZnO films with different conduction types depending on the N/Ga flux ratio in doping process. The PL spectra show evident competition between neutral-donor bound exciton (D0X) and neutral-acceptor bound exciton (A0X) according to the N/Ga ratio. From the temperature-dependent PL spectra, the nitrogen acceptor level was identified to be about 126 meV in (N,Ga)-doped p-type ZnO. / For nitrogen doping of ZnO thin films, DMHy was used as the nitrogen dopant source. A narrow temperature window from about 500°C to 550°C for efficient nitrogen doping was identified. However, p-type ZnO was not obtained by nitrogen mono-doping, which results from the low solubility of N and the self-compensating effect of native defects, and/or N-induced complexes. By co-doping N with Ga in proper ratios, p-type ZnO films were successfully achieved with a high hole concentration of 3.51 x 1017 --2.41 x 1018cm-3, Hall mobility of 1.1 --4.29 cm2/V-s and resistivity of 0.6 -- 16.2 O cm. But the conduction type critically depends on the growth conditions. Based on the successfully fabrication of (N,Ga)-doped p-type ZnO, a p-ZnO:(N,Ga)/n-ZnO homojunction was fabricated. The I-V measurement shows clear rectifying behavior with a turn-on voltage of about 3.7 V. / Further investigation of the effect of N/Ga doping ratios on the conduction type of ZnO samples reveals that successful doping depends much on engineering a stable local chemical bonding environment. Under mono-doping conditions (via N-Zn4), nitrogen solubility is limited and nitrogen acceptors are readily compensated by native donors and/or N-related donors; under appropriate N/Ga flux ratios, cluster-doping (via Ga-N3O and Ga-N4) can be realized to achieve p-type ZnO; while excessively high N/Ga ratios cause the doped ZnO n-type conductivity again, which may be because that under excessively high N/Ga ratio range, N-Zn4 configuration dominates and thus cause more N-related donors and degrade the ZnO film quality, similar as the mono-doping case. By tuning the N/Ga ratio in doping, it is expected to create appropriate chemical environments to enhance the formation of desired dopant species for stable p-type ZnO. / In this work, Metal-organic chemical vapour deposition (MOCVD) growth of ZnO and its p-type doping have been studied. The group V element N was used as primary dopant to make ZnO p-type. In the growth of ZnO by MOCVD, it was found that the structural and morphological properties of deposited ZnO strongly depend on growth conditions. Low VI/II ratio and high growth rate favor the growth of ZnO nanostructures (nanowires, nanobelts); while high VI/II ratio and low growth rate favor the growth of ZnO thin films. / The semiconductor ZnO is currently gaining intense interest in the research community because of its prospect in optoelectronic applications, such as blue/ultraviolet emitters and detectors, and high speed electronic devices. However, making reliable and reproducible p-type ZnO is still a bottleneck, which impedes the practical application of ZnO-based devices. The difficulty is mainly due to the self-compensation effect of native defects and the low solubility limit of acceptor dopants. Although substantial research is currently being carried out worldwide towards this goal, the effective p-type dopant and its doping process have not yet been identified. / Wang, Hui. / "Apr 2008." / Adviser: Aaron H. P. Ho. / Source: Dissertation Abstracts International, Volume: 70-03, Section: B, page: 1860. / Thesis (Ph.D.)--Chinese University of Hong Kong, 2008. / Includes bibliographical references. / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. [Ann Arbor, MI] : ProQuest Information and Learning, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstracts in English and Chinese. / School code: 1307.
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Allosteric interactions in coordination cagesRizzuto, Felix January 2018 (has links)
Biomolecular receptors can catalyse reactions, alter their geometry, and inhibit their activity in response to molecules binding around their periphery. Synthetic receptors that can mimic this allosteric binding behaviour extend the potential applications of host-guest chemistry to programmable molecular systems. Modulating the degree and magnitude of interaction between components within these systems enables the design of chemical behaviour akin to biological complexity. With a view to developing artificial guest-binding regulation systems, a series of metal-organic cages capable of both the peripheral and internal encapsulation of guests are presented: octahedra capable of accommodating two guests in different locations simultaneously; cuboctahedral receptors that bind fullerenes with all-or-nothing positive cooperativity and assemble supramolecular entities internally; a heteroleptic triangular prism capable of recognising steroids and enantiopure natural products; and a tetrahedron that binds fullerene clusters. Each of these architectures employs one or more binding site to either: a) template specific products; b) regulate the cooperativity of binding of large anionic guests; c) assemble coordination complexes and interlocked species inside their cavities; d) alter their morphology in well-defined ways; or e) form assemblies with new electronic and electrochemical functionality. In all cases, chemical systems that respond to multiple stimuli simultaneously are explored, and new applications for bringing multiple species into proximity are detailed. The allosteric binding motifs described herein can be extended to sort reaction mixtures, generate specific isomeric forms, stabilise labile species and promote tuneable modes of intermolecular cooperativity.
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