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71	CHEMICAL HYDRIDE REACTOR DESIGNS FOR PORTABLE FUEL CELL DEVICES Benjamin Hynes (8086172) 05 December 2019 (has links) <div> <p>This research addresses the issues of electrical energy storage that warfighters in the U.S. military face. A device is presented that combines an on-demand hydrogen reactor with a state of the art proton exchange membrane fuel cell. This thesis focuses on the design criteria and analysis of the chemical hydride reactor. On demand hydrogen release can occur by controlling the hydrolysis reaction of Ammonia Borane (AB). Maleic acid is used to promote rapid release of hydrogen and trap the ammonia released from AB. Reactor designs are categorized as either delivering liquid or solid ammonia borane into an acid filled reactor. In an effort to design as simple of a system as possible, the delivery mechanisms presented do not use electronically powered devices. The primary safety criterion is that the hydrogen does not overly pressurize and meets the consumption rate of the fuel cell. Two liquid delivery architectures are proposed and tested using the assumption that a pressure differential between two chambers will deliver ammonia borane solution into a reactor. Methods of controlling the exposure of solid ammonia borane to a promoter is also presented. Pressed AB pellets were experimentally analyzed in order to characterize the interaction of solid AB in acidic solution. Designs are ranked against each other using system parameters that are applicable to man portable device. Liquid delivery architectures provided a safe and robust method of hydrolysis control. A bag reactor system that met the hydrogen requirements of a fuel cell was developed and tested. When used to compliment a fuel cell and military grade batteries, such a reactor will save weight and volume for extended missions requiring electronic equipment.<b></b></p> </div> <b><br></b> Engineering not elsewhere classified Military equipment proton exchange fuel cells ammonia borane hydrolysis hydrogen storage Portable electronics
72	Development of Hydrogen-Based Portable Power Systems for Defense Applications Taylor B Groom (9154769) 29 July 2020 (has links) <p>This dissertation describes the design and characterization of a lightweight hydrogen reactor coupled to a proton exchange membrane fuel cell for portable power delivery. The system is intended to recharge portable batteries in the absence of an established electrical power supply. The presented work can be divided into two endeavors; the first being an investigation of various hydrogen generation pathways and the second being the design, fabrication, and testing of a system to house hydrogen generation and deliver electrical power.</p> <p>Two hydrogen storage materials are considered for this work: ammonia borane and sodium borohydride. Organic acids are investigated for their ability to accelerate the hydrolysis of either material and generate hydrogen on-demand. In the case of ammonia borane, organic acids are investigated for a secondary role beyond reaction acceleration, serving also to purify the gas stream by capturing the ammonia that is produced during hydrolysis. Organic acids are found to accelerate the hydrolysis of ammonia borane and sodium borohydride with relative indifference towards the purity of water being used. This is advantageous as it allows the user to collect water at the point of use rather than transport highly pure water for use as a reactant. Collecting water at the point of use increases system energy density as only ammonia borane or sodium borohydride and an organic acid are transported with the system hardware.</p> <p>A custom hydrogen reactor is developed to facilitate hydrolysis of ammonia borane or sodium borohydride. The reactor is paired with a fuel cell to generate electrical power. The rate of hydrogen being generated by the system is modulated to match the fuel cell’s consumption rate and maintain a relatively constant pressure inside the reactor. This allows the system to satisfy a wide range of hydrogen consumption rates without risking over pressurization. The system is shown to produce up to 0.5 sLpm of hydrogen without exceeding 30 psia of hydrogen pressure or a temperature rise greater than 35°C.</p><p>The envisioned use for this system is portable battery charging for expeditionary forces within the United States military. This application informed several design choices and is considered when evaluating technological maturation. It is also used to compare the designed system to existing energy storage technologies.</p> Hydrogen Fuel Cell Energy Chemical Hydrides Sodium Borohydride Ammonia Borane Portable Energy Storage
73	A study of ammonia borane and its derivatives Ryan, Katharine Rachel January 2011 (has links) This thesis reports the investigation of molecular materials for hydrogen storage applications with a particular emphasis on alkali-metal amidoboranes. I have developed new routes for the synthesis of $alpha$-LiNH$_{2}$BH$_{3}$ and NaNH$_{2}$BH$_{3}$, and have studied their hydrogen storage properties by thermogravimetric analysis, variable temperature X-ray and neutron diffraction and inelastic neutron scattering. I report the synthesis and full structural characterization of two new materials, KNH$_{2}$BH$_{3}$ and $beta$-LiNH$_{2}$BH$_{3}$, and have performed initial studies on a tetragonal phase of a variant of LiNH$_{2}$BH$_{3}$ with a preliminary structure solution. I have also performed variable temperature neutron diffraction on ammonium borodeuteride, ND$_{4}$BD$_{4}$, and report the full structural characterisation of the three phases identified as a result of these measurements. Furthermore, variable temperature inelastic neutron scatting (INS) measurements were performed on ammonia borane, NH$_{3}$BH$_{3}$, and the results are discussed in terms of crystallographic phase changes. 620.112
74	A Combined Theoretical and Experimental Study on Deposition of Solid State Materials Lee, Veronica 08 1900 (has links) Deposition of solid state materials span a wide variety of methods and often utilize high energy sources such as plasmas and ultra-violet light resulting in a wide variety of characteristics and applications. A fundamental understanding is essential for furthering the applications of these materials which include catalysis, molecular filtration, electronics, sensing devices, and energy storage among others. A combination of experimental and theoretical work is presented here on several materials including 2D silicates on Pd, boron oxide, and vanadium oxynitride. Silicate formation under low energy electron microscopy demonstrate film permeability to oxygen, while ab initio molecular dynamics simulations reveal the possible initial mechanisms associated with the formation of boron oxide films during atomic layer deposition. Lastly, vanadium oxynitrides have shown preferential sputtering of N over O sites and theoretical binding energies serve as a guide for assigning experimental x-ray photoelectron spectra. Atomic Layer Deposition Low Energy Electron Microscopy Molecular Dynamics 2D Silicate Vanadium oxynitrides Boron oxide Trimethoxy borane Chemistry, Analytical Chemistry, Physical Chemistry, Inorganic
75	Computational Studies On Macropolyhedral Boranes And Metallaboranes Shameema, O 08 1900 (has links) The analysis of nature of bonding in non-classical structures is always an intriguing area of research. Typical examples of such systems are polyhedral boranes that exhibit fascinating cluster bonding where the traditional 2-center-2-electron (2c-2e) bond model fails. This thesis involves the investigation of such polyhedral borane structures and their reactivity by employing both qualitative and quantitative tools of electronic structure theory. There is an intense current interest in the macropolyhedral boranes for their applications pharmaceuticals and materials chemistry. The mno rule had been formulated to account for the electronic requirements for the macropolyhedral structures. Though useful in explaining and designing structures, electron counting rules provide a yes or no answer; not all the molelcules having stipulated number of electrons are equally stable. We have used the concept of orbital compatibility to explain the relative energies of different macropolyhedral structural patterns such as closo-closo, closo-nido and nido-nido. One of the major problems in polyhedral boron cage chemistry has been the lack of general synthetic routes for the construction of large cage systems . With this view, we explored the mechanism of the reaction of macropolyhedron B20H16 with MeCN and similar ligands, which provide an understanding of the skeletal rearrangement that occur in macropolyhedral boranes. This can help in the design and synthesis of new macropolyhedral boranes. The early examples of metallaboranes were found to adopt structures which are analogous to that of boranes and carboranes. Hypercloso metallaboranes have closo structure with less number of electrons than required by Wades rule. We have carried out a detailed DFT analysis to explore the structure and electronic relationship of 9-12 vertex closo and hypercloso structures of both borane and metallaboranes. Calculations show that in vertex hypercloso metallaborane needs only n skeleton electron pairs rather than n+1 as suggested by Wade’s rules. Stabilization of supraicosahedral boranes with more than 12 vertices by substituting BH groups by transition metal fragments is also explored with DFT calculations. Calculations show that as the number and the size of the metal atom increases the stability of supraicosahedral and condensed supraicosahedral borane structures also increases. These studies will open up new possibilities for the development of polyhedral clusters of extraordinary size. Metallaboranes Boranes Macropolyhedral Boranes Polyhedral Boranes - Condensation Polyhedral Borane - Electronic Structure Supraicosahedral Boranes Polyhedral Boranes Hypercloso Metallaborane Density Functional Theory Boron Inorganic Chemistry
76	Amine-Boranes: Synthesis and Applications Henry J Hamann (10730742) 30 April 2021 (has links) Reported herein is a brief summary of the history, properties, and applications of amine-boranes. The past methods devised for their preparation are described and the routes used to produce the compounds used in the work presented here are detailed. Building on prior synthetic approaches to amine-boranes, a new carbon dioxide mediated synthesis is presented. Proceeding through a monoacyloxyborane intermediate, the borane complexes of ammonia, primary, secondary, tertiary, and heteroaromatic amine are provided in 53-99% yields. Utilizing the amine-boranes obtained from the methods described, two divergent methods for direct amidation are introduced. The first uses amine-boranes as dual-purpose reagents, where the carboxylic acid is first activated by the borane moiety to form a triacyloxyborane-amine complex. This allows the delivery of the coordinated amine to form the amide products. A series of primary, secondary, and tertiary amides were prepared in 55-99% yields using this protocol, which displays a broad functional group tolerance. Extended from this dual-purpose methodology, a catalytic amidation is described. Utilizing ammonia-borane as a substoichiometric (10%) catalyst, a series of secondary and tertiary amide are prepared directly from carboxylic acids and amines in 59-99% yields, including amines containing typically borane reactive functionalities including alcohols, thiols, and alkenes. Amine-boranes are additionally used in two borylation methodologies. By reaction with <i>n</i>-butyl lithium, the amine-boranes are converted to the corresponding lithium aminoborohydrides, which upon reaction with a terminal alkyne provides the alkynyl borane-amine complexes in 65-98% yields. This process is compatible with both alkenes and internal alkynes, as well as a range of aprotic functionalities. A new strategy for aminoborane synthesis is also described and applied to the borylation of haloarenes. Activation of a series of amine-boranes with iodine produces the iodinated amine-borane, which undergoes dehydrohalogenation with an appropriate base to produce either monomeric or dimeric aminoboranes. Several aminoboranes were synthesized exclusively as the monomeric species, which due to their greater reactivity, were used directly in the synthesis of a series of aryl boronates in 65-99% yields. Organic Chemistry Organic Chemical Synthesis Catalysis and Mechanisms of Reactions amine-boranes Aminoboranes amidation borylation synthesis methodology metal amidoboranes triacyloxyborane-amine ammonia-borane aminoborohydrides boronate esters
77	Experimental Electron Density Determination of Unconventionally Bonded Boron / Experimentelle Elektronendichteuntersuchungen von Bor in außergewöhnlichen Bindungssituationen Flierler, Ulrike 28 April 2009 (has links) No description available. 540 Chemie Mathematics and Computer Science Röntgenstrukturanalyse Quantentheorie von Atomen in Molekülen Bor Borane Borylene x-ray diffraction quantum theory of atoms in molecules boron borane borylene 35.11 35.25 35.90 SF 000: Quantenchemie SP 000: Strukturchemie STL 100: Bor {Anorganische Chemie}
78	Hydrierung von Bortrichlorid mit molekularem Wasserstoff in Gegenwart von Aminen als Hilfsbasen Schellenberg, René 25 May 2011 (has links) (PDF) In dieser Arbeit wurde die Möglichkeit untersucht, Bortrihalogenide mit Wasserstoff unter milden Bedingungen (T < 100 °C, p(H2) < 50 bar) zu hydrieren. Um eine Triebkraft für die thermodynamisch ungünstige Reaktion zu erhalten, wurden Amine als Hilfsbasen zugesetzt, welche den bei der Reaktion entstehenden Halogenwasserstoff als Ammoniumsalz binden und damit das Reaktionsgleichgewicht in Richtung der Produkte verschieben. Es wurden dafür verschiedene Amin-Boran bzw. Amin-HCl Addukte synthetisiert und mittels IR, NMR und DSC charakterisiert. Bei den anschließenden Hydrierungsversuchen wurden verschiedene Katalysatoren auf ihre Eignung getestet und weiterentwickelt. Unterstützt wurden die experimentellen Arbeiten durch Berechnungen mit Gaussian 03. IR- und NMR-Spektren vieler Addukte wurden berechnet und freie Reaktionsenthalpien der Hydrierung in Abhängigkeit des verwendeten Amins und Borhalogenids bestimmt. Mögliche Übergangszustände wurden diskutiert und ihre Aktivierungsenergien ermittelt. Hydrierung Hydrodehalogenierung Hydrodechlorierung Borhalogenide Hydroborane Silane NMR IR DSC Gaussian Wasserstoffspeicherung Recycling Borazan Boran-Amin-Addukt Reaktionsenthalpie Aktivierungsenergie hydrogen storage ammonia borane recycling boron halides boron hydrides borane amine adducts NMR IR DSC Gaussian hydrogenation hydrodechlorination reaction enthalpy activation energy ddc:546 Hydrierung Amine Bortrihalogenide Molekülspektroskopie Differential scanning calorimetry
79	Hydrierung von Bortrichlorid mit molekularem Wasserstoff in Gegenwart von Aminen als Hilfsbasen Schellenberg, René 05 May 2011 (has links) In dieser Arbeit wurde die Möglichkeit untersucht, Bortrihalogenide mit Wasserstoff unter milden Bedingungen (T < 100 °C, p(H2) < 50 bar) zu hydrieren. Um eine Triebkraft für die thermodynamisch ungünstige Reaktion zu erhalten, wurden Amine als Hilfsbasen zugesetzt, welche den bei der Reaktion entstehenden Halogenwasserstoff als Ammoniumsalz binden und damit das Reaktionsgleichgewicht in Richtung der Produkte verschieben. Es wurden dafür verschiedene Amin-Boran bzw. Amin-HCl Addukte synthetisiert und mittels IR, NMR und DSC charakterisiert. Bei den anschließenden Hydrierungsversuchen wurden verschiedene Katalysatoren auf ihre Eignung getestet und weiterentwickelt. Unterstützt wurden die experimentellen Arbeiten durch Berechnungen mit Gaussian 03. IR- und NMR-Spektren vieler Addukte wurden berechnet und freie Reaktionsenthalpien der Hydrierung in Abhängigkeit des verwendeten Amins und Borhalogenids bestimmt. Mögliche Übergangszustände wurden diskutiert und ihre Aktivierungsenergien ermittelt.:1. Einleitung und Problemstellung 2. Stand der Wissenschaft 2.1. Allgemeines 2.2. Die Amin-Boran-Addukte 2.3. Hydrierung mit Wasserstoff 2.3.1. Allgemeine Konzepte 2.3.2. Katalytische Hydrierung 2.3.3. Thermodynamische und kinetische Betrachtungen 2.4. Hydrierung mit Hydrosilanen 2.5. Quantenchemische Berechnungen 2.5.1. Grundlagen 2.5.2. Die Dichtefunktionaltheorie 2.5.3. Basissätze 2.5.4. Die Optimierungsverfahren 2.5.5. Übergangszustandsrechnungen 2.5.6. Weitere verwendete Methoden 2.6. 11B-NMR 3. Geräteteil 4. Durchgeführte Synthesen 4.1. Synthese von N-Ethyldiphenylamin 4.2. Synthese von N-Ethylbis(p-tolyl)amin 4.3. Synthese der BN-Addukte 4.4. Synthese der HCl-Addukte 4.5. Synthese von P-1 Nickel 5. Ergebnisse 5.1. Berechnungen mit Gaussian 5.1.1. Das Reaktionssystem auf Grundlage des Bortrichlorids 5.1.2. Die Hydrierung von Bortribromid und Bortriiodid mit Wasserstoff 5.1.3. Hydrierung mit Triethylsilan 5.1.4. Zusammenfassende Betrachtung der berechneten Ergebnisse 5.2. Die Addukte 5.2.1. Die "Amingrundtypen" 5.2.2. Die Addukte modifizierter Amine 5.2.3. Zusammenfassung 5.3. Hydrierung mit Triethylsilan 5.3.1. Allgemeines 5.3.2. Vergleich der Hydrierung der Bortrichlorid-Addukte von Triethylamin und N,N-Diethylanilin 5.3.3. Hydrierung bei verschiedenen Temperaturen 5.3.4. Zusammenfassung 5.4. Hydrierung mit Wasserstoff 5.4.1. Allgemeines 5.4.2. Hydrierversuche im Einkammerreaktor 5.4.3. Hydrierversuche im Zweikammerreaktor 5.4.4. Zusammenfassung 5.5. Weitere durchgeführte Experimente 5.5.1. Hydrierung von Disilanen 5.5.2. Zusatz von Chloridakzeptoren 6. Zusammenfassung und Ausblick 7. Anhang 7.1. Analytische Daten und Produktidentifizierung 7.1.1. NMR-Daten 7.1.2. IR-Daten 7.1.3. Einkristalldaten 7.2. Gaussian 03 Daten 7.2.1. Energien der Grundzustände 7.2.2. Energien der Übergangszustände 7.2.3. Berechnete IR-Spektren 7.2.4. Berechnete Reaktionsgrößen 7.2.5. Isotrope Abschirmungen 7.3. DSC-Daten 7.3.1. Boran-Amin-Addukte 7.3.2. HCl-Amin-Addukte 7.4. Die Hydrierungsansätze 8. Literaturverzeichnis 9. Formelverzeichnis info:eu-repo/classification/ddc/546 ddc:546
80	B(C6F5)3-catalyzed reductions with hydrosilanes: scope and implications to the selective modification of poly(phenylsilane) Lee, Peter Tak Kwong 23 December 2015 (has links) New complex silicon-containing molecules were made by B(C6F5)3-catalyzed hydrosilation, dehydrocoupling, and dealkylative coupling reactions starting from Si-H reagents. The scope of reactions starting from disilane was expanded to include the formation of silicon-sulfur1, silicon-oxygen and silicon-alkyl side-chains. Reaction inhibition was found with some heteroatom substrates, such as phenols and imines, that strongly bound to B(C6F5)3, and was consistent with the proposed mechanism (Chapter 2). B(C6F5)3 was found to be selective for Si-H activation in reactions of disilane and no competing Si-Si bond cleavage side-reactions were observed. This result will guide future studies and application of B(C6F5)3-catalyzed reactions with polysilanes. A different type of selectivity, the competing B(C6F5)3-catalyzed over-reduction, is evaluated and discussed in Chapter 3. This over-reduction reaction was classified into two distinct cases: alkyl groups for which over-reduction reaction was dependent on the steric bulk of the alkyl group and benzylic groups for which over-reduction was dependent on having an alpha-aryl group. These reactions are consistent with the proposed Piers-Oestreich mechanism (see Chapter 3) and suggest the rate-determining step for over-reduction is the nucleophilic attack of the alkoxysilane (R -O-SiR3) to the R3Si•••H•••B(C6F5)3 complex. Benzylic side-chains were over-reduced regardless of the steric bulk of the aryl groups. Literature precedents suggest that benzyl over-reductions must undergo an alternative mechanism to the Piers-Oestreich mechanism. A number of mechanisms have been proposed in the literature and in Chapter 3, suggesting conventional heteroatom substrate borane or silane-borane complexation. Furthermore, over-reduction of benzylic sulfur containing side-chains was found and this reaction was exploited in the B(C6F5)3-catalyzed synthesis of unique silicon-sulfur silicon-containing products. These over-reduction reactions highlighted the role of the silane for over-reduction and the challenges associated with the post-polymerization modification of poly(phenylsilane). The advances in B(C6F5)3-catalyzed synthesis of small silane molecules suggested reaction conditions and gave spectroscopic benchmarks that were applied to the post polymerization modification of poly(phenylsilane) (Chapter 4). New X-modified poly(phenylsilane) derivatives with thiolato (sulfur), alkoxy/aryloxy (oxygen), amido (nitrogen) and alkyl(carbon) side-chains were prepared with 10-40% incorporation of the ‘X’ group into poly(phenylsilane). These new polysilanes were characterized by the following methods: 1H/13C/29Si NMR, IR, MALS-GPC, EA, and UV-vis absorption spectroscopy. Together, these characterization methods showed that the polysilane had not undergone Si-Si cleavage and thus demonstrated the utility of B(C6F5)3 for the selective activation of Si-H bonds. Thermal decomposition of X-modified poly(phenylsilane) derivatives and parent poly(phenylsilane) showed interesting redistribution pathways (Chapter 5). The thermal decomposition products of poly(phenylsilane) were identified: volatile monosilanes, a structurally complex not-yet-identified phenylsilicon-containing material generated at 500 °C, and a mixture of silicon carbide (SiC) and elemental carbon generated at 800 °C. The B(C6F5)3-catalyzed post-polymerization method (Chapter 4) was evaluated based on the substitution percentage for X-functionalized poly(phenylsilane) derivatives. Reactions of highly electron-donating substrates gave a low amount of X incorporation (10%, e.g. aryloxy side-chains derived from phenol). Aryloxy groups were alternatively introduced via demethanative coupling, which gave a polymer with a greater substitution percentage (25%). The overall impact of the H-to-X substitution reactions was gauged by UV-vis absorption spectra and desirable UV absorption properties would require the modified poly(phenylsilane) to have a high degree of substitution. / Graduate / 2017-09-02 polysilane poly(phenylsilane) hydrosilation dehydrocoupling dealkylative coupling demethanative coupling over-reduction reduction with silanes post-polymerization modification tris(pentafluorophenyl)borane 29Si NMR thermolysis redistribution silicon-silicon bonds thermogravimetric analysis UV-vis absorption sym-tetraphenyldisilane

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