Caracterização do PolyParaPhenylene (PPP) dopado com FeCl3, utilizando espectroscopia de alta resolução por ressonância magnética nuclear / Characterization of FeCl3-doped PolyParaPhenylene (PPP) using high resolution nuclear magnetic resonance spectroscopy

Giotto, Marcus Vinicius

19 April 1993

O objetivo deste trabalho consiste na caracterização do polímero PolyParaPhenylene (PPP) dopado com FeCl3, usando a técnica de Espectroscopia de Alta Resolução em Sólidos por Ressonância Magnética Nuclear. Os espectros de alta resolução de 13C foram obtidos usando, simultaneamente, as técnicas de desacoplamento em alta potencia (DEC) e rotação da amostra em torno do angulo mágico (MASS). Alterações nos espectros de 13C do PPP dopado com FeCl3 causadas por defeitos na cadeia polimérica, tal como polarons e bipolarons, foram analisadas. Efeitos de variação de temperatura e purificação sobre os espectros do PPP, também foram estudados. As amostras foram, adicionalmente, caracterizadas por outras técnicas espectroscópicas, tal como Ressonância Paramagnética Eletrônica (EPR), Efeito Mossbauer, Infra Vermelho e Absorção Atômica; bem como por medidas de Condutividade. Nos observamos que as alterações nas larguras de linha de RMN, estão relacionadas com o aparecimento de bipolarons na cadeia polimérica. / The objective of this work consist of the characterization of FeCl3 doped PolyParaPhenylene (PPP) polymer, using Solid State High Resolution Nuclear Magnetic Resonance Spectroscopy. The 13C high resolution spectra were obtained simultaneously using High Power Decoupling (DEC) and Magic Angle Sample Spinning (MASS) techniques. Alterations in the high resolution 13C spectra of FeCl3 doped PPP caused by defects in the polymer chain such as polarons and bipolarons were analyzed. Effect of temperature variation and purification upon the PPP spectra was also studied. The samples were additionally characterized by others spectroscopic techniques such as Electron Paramagnetic Resonance (EPR), Mossbauer Effect, Infrared and Atomic Absorption as well as by conductivity measurements. We observed that the NMR linewidth changes are related to appearance of the bipolaron in the polymeric chain

Espectroscopia

Estado Solido

FeCl3

FeCl3

PolyParaPhenylene

PolyParaPhenylene

PPP

PPP

RMN

Solid-State NMR

Spectroscopy

Hybrid Solid-State Hydrogen Storage Materials

Benge, Kathryn Ruth

January 2008

This thesis investigates the chemistry of ammonia borane (NH3BH3) relevant to the development of hydrogen storage systems for vehicular applications. Because of its high hydrogen content and low molecular weight ammonia borane has the potential to meet stringent gravimetric hydrogen storage targets of gt;9 wt%. Two of the three moles of H2 in ammonia borane can be released under relatively mild conditions, with the highest gravimetric yield obtained in the solid-state. However, ammonia borane does not deliver sufficient H2 at practical temperatures and the products formed upon H2 loss are not amenable to regeneration back to the parent compound. The literature synthesis of ammonia borane was modified to facilitate large scale synthesis, and the deuterated analogues ND3BH3 and NH3BD3 were prepared for the purpose of mechanistic studies. The effect of lithium amide on the kinetics of dehydrogenation of ammonia borane was assessed by means of solid-state reaction in a series of specific molar ratios. Upon mixing lithium amide and ammonia borane, an exothermic reaction ensued resulting in the formation of a weakly bound adduct with an H2N...BH3-NH3 environment. Thermal decomposition at or above temperatures of 50eg;C of this phase was shown to liberate gt;9 wt% H2. The mechanism of hydrogen evolution was investigated by means of reacting lithium amide and deuterated ammonia borane isotopologues, followed by analysis of the isotopic composition of evolved gaseous products by mass spectrometry. From these results, an intermolecular multi-step reaction mechanism was proposed, with the rates of the first stage strongly dependent on the concentration of lithium amide present. Compounds exhibiting a BN3 environment (identified by means of solid-state sup1;sup1;B NMR spectroscopy) were formed during the first stage, and subsequently cross link to form a non-volatile solid. Further heating of this non-volatile solid phase ultimately resulted in the formation of crystalline Li3BN2 - identified by means of powder X-ray diffractometry. This compound has been identified as a potential hydrogen storage material due to its lightweight and theoretically high hydrogen content. It may also be amenable to hydrogen re-absorption. The LiNH2/CH3NH2BH3 system was also investigated. Thermal decomposition occurred through the same mechanism described for the LiNH2/NH3BH3 system to theoretically evolve gt;8 wt% hydrogen. The gases evolved on thermal decomposition were predominantly H2 with traces of methane detected by mass spectrometry.

ammonia borane

Hydrogen storage

Hydrogen

methylamine borane

lithium amide

11B NMR

solid-state NMR

A Solid-State 11B NMR and Computational Study of Boron Electric Field Gradient and Chemical Shift Tensors in Boronic Acids and Boronic Esters

Weiss, Joseph

04 February 2011

The results of a solid-state 11B NMR study of a series of boronic acids, boronic esters, and boronic acid catechol cyclic esters with aromatic substituents are reported in this thesis. Boron-11 electric field gradient (EFG) and chemical shift (CS) tensors obtained from analyses of spectra acquired in magnetic fields of 9.4 T and 21.1 T are demonstrated to be useful for gaining insight into the molecular and electronic structure about the boron nucleus. It can be concluded that when adequate electronic variation is present in the compounds being studied, Ω is generally the most characteristic boron NMR parameter of the molecular and electronic environment for boronic acids and esters. Importantly, these data are only reliably accessible in ultrahigh magnetic fields. The experimental span values result from a delicate interplay of several competing factors, including hydrogen bonding, the value of the dihedral angle, and the type of aromatic ring system present.

SSNMR

boron

solid-state NMR

electric field gradient

chemical shift tensor

NMR

A Solid-State 11B NMR and Computational Study of Boron Electric Field Gradient and Chemical Shift Tensors in Boronic Acids and Boronic Esters

Weiss, Joseph

04 February 2011

The results of a solid-state 11B NMR study of a series of boronic acids, boronic esters, and boronic acid catechol cyclic esters with aromatic substituents are reported in this thesis. Boron-11 electric field gradient (EFG) and chemical shift (CS) tensors obtained from analyses of spectra acquired in magnetic fields of 9.4 T and 21.1 T are demonstrated to be useful for gaining insight into the molecular and electronic structure about the boron nucleus. It can be concluded that when adequate electronic variation is present in the compounds being studied, Ω is generally the most characteristic boron NMR parameter of the molecular and electronic environment for boronic acids and esters. Importantly, these data are only reliably accessible in ultrahigh magnetic fields. The experimental span values result from a delicate interplay of several competing factors, including hydrogen bonding, the value of the dihedral angle, and the type of aromatic ring system present.

SSNMR

boron

solid-state NMR

electric field gradient

chemical shift tensor

NMR

EXPERIMENTAL SOLID STATE NMR OF GAS HYDRATES: PROBLEMS AND SOLUTIONS

Moudrakovski, Igor L., Lu, Hailong, Ripmeester, John A., Kumar, Rajnish, Susilo, Robin, Luzi, Manja

07 1900

Solid State NMR spectroscopy has taken a very prominent place among the many spectroscopic techniques employed for the characterization of clathrate hydrates. Exceptionally high sensitivity of the spectra to the molecular environment and dynamic processes, together with the ability to provide accurate and quantitative data make NMR spectroscopy a highly desirable and versatile approach for studying hydrates. Application of the method to its full capacity, however, requires some extensive instrumental developments to adapt it to the specific experimental requirements of hydrate studies, for example, very low temperatures and high pressures. In this presentation we will give an overview of recent Solid State NMR advances in various areas of hydrate research. Examples will include analysis of the composition and structure of mixed gas hydrates prepared from multi-component mixtures of hydrocarbons, characterization of the natural gas hydrates from different sources, and evaluation of formation conditions and properties of mixed hydrogen hydrates. 13C NMR with Magic Angle Spinning (MAS) at -100C has been the main approach in the first two examples. We will discuss the requirements and the necessary instrumental developments to make the experiments of this type successful. The detailed characterization of mixed hydrogen hydrates required low temperature 1H MAS. Problems of quantification in these experiments will be discussed. We expect that all these recent experimental developments will prompt wider application of Solid State NMR in hydrate research.

Solid State NMR

gas hydrates

structure

cage occupancy

composition

ICGH

International Conference on Gas Hydrates

Many body dynamics in nuclear spin diffusion

Dumez, Jean-Nicolas

04 July 2011

Since its introduction by Bloembergen in 1949, nuclear spin diffusion has been a topic of significant interest in magnetic resonance. Spin diffusion, which can be defined as the transfer of spin polarisation induced by the dipolar interaction, is a ubiquitous transport mechanism in solids. Experimental observations of spin diffusion contain structural information. However, the many-body nature of the problem makes it difficult to describe from first principles. The central goal of this thesis is to obtain a quantitative description of the spin diffusion phenomenon from first-principles, through the development of suitable models of the underlying many-body dynamics. To that end we first consider an extension of an existing approach that relies on a master equation to describe the polarisations, for the case of proton-driven carbon-13 spin diffusion (PDSD). Second, a novel approach is introduced for the simulation of the time evolution of selected observables for large strongly coupled nuclear spin systems, using low-order correlations in Liouville space (LCL). Following the introduction of this new simulation method, Liouville-space reduction in solids is analysed in more detail, in order to identify the conditions under which the LCL approximation is valid. Finally, using the LCL model, simulations of proton spin diffusion (PSD) and PDSD are performed, directly from crystal geometry and with no adjustable parameters, and are found to be in excellent agreement with experimental measurements for polycrystalline organic solids.

[CHIM:OTHE] Chemical Sciences/Other

Spin diffusion

Solid-state NMR spectroscopy

Magnetic resonance

Numerical simulation

Solid-State NMR Studies of Solvent-Accessible Fragments of a Seven-Helical Transmembrane Protein Proteorhodopsin

Ward, Meaghan

12 September 2011

High–resolution multidimensional proton-detected NMR was used to study the solvent-exposed regions of a seven-helical integral membrane proton pump proteorhodopsin (PR). Fully deuterated PR samples with protons reintroduced to solvent-accessible sites through back exchange were prepared and found to produce NMR spectra with acceptable proton resolution (~0.2 ppm). Novel three-dimensional proton-detected chemical shift correlation spectroscopy was used for the identification and resonance assignment of the solvent–exposed regions of PR. Though most of the observed residues were located at the membrane interface there were notable exceptions, particularly in helix G. This helix contains the Schiff base-forming Lys231 and many conserved polar residues in the extracellular half. Solvent accessibility of helix G supports the hypothesis that high mobility of the F-G loop could transiently expose a hydrophilic cavity in the extracellular half of PR, and implies that such a cavity may be part of the protein’s proton-conduction pathway. / Natural Sciences and Engineering Research Council, Ontario Ministry of Training, Colleges, and Universities, Canadian Foundation for Innovation, Ontario Ministry of Research and Innovation, University of Guelph

Proteorhodopsin

solid-state NMR

magic angle spinning

Double Quantum Coherence

membrane proteins

protein-water interaction

Site-Specific Solid-State NMR Studies of the Protein-Water Interface of Anabaena Sensory Rhodopsin

Ritz, Emily

14 September 2012

Solid-state NMR spectroscopy was used to site-specifically investigate the protein-water interface of a seven alpha-helical transmembrane protein, Anabaena sensory rhodopsin (ASR). Water-edited experiments, which employ a T2-filter to select for mobile protons, provided a means to detect residues which appear to be in close contact to water molecules, and to gain insights about the water-protein interface of ASR. First, through the application of Lee-Goldburg homonuclear decoupling, it was determined that polarization transfer across this interface is dominated by through-space interaction mechanisms, as opposed to chemical exchange. A series of two-dimensional experiments were also performed to detect polarization transfer along the backbone and to the sidechains of the protein. Residues located in solvent-accessible regions of the protein, such as the B-C loop, were found to obtain polarization quickly, as expected, and in agreement with previous H/D exchange data. Residues known to be in contact with bound crystal water molecules were also detected. In addition to these, we found new residues which appear to be in contact with water, indicating additional HN-H2O interactions, or additional contacts with bound water molecules. Most of these residues were located beside exchangeable regions of ASR. Sidechains of residues located in the cytoplasmic side of helix F were seen to be in close contact with mobile water molecules, supporting evidence of a hydrophilic chain along the cytoplasmic half of the protein, which is suggested to cause a functional outward tilt of the cytoplasmic half of helix F upon light-activation.

solid-state NMR

rhodopsin

protein-water interactions

water-edited

biophysics

proton exchange

T2-filter

Multinuclear magnetic resonance investigations of structure and order in borates and metal cyanides

Aguiar, Pedro Miguel

14 September 2007

The local information provided by nuclear magnetic resonance (NMR) makes it an ideal method for the structural investigations of materials lacking extended long-range ordering. This work focuses on investigations of two types of materials possessing very different types of disorder. The first section involves investigations of alkali borate glasses and the application of solid-state NMR techniques to probe short- and medium-range ordering in such glasses. Differences between the various alkali borates over a wide compositional range are probed using one and two-dimensional techniques. The use of double-resonance dipolar recoupling techniques to investigate cesium-boron distances is investigated. The second section probes a series of transition-metal cyanide coordination polymers. The bidentate nature of the cyanide ligand allows for the possibility of forming numerous isomers. Information about the isomer(s) present is gained via the various NMR parameters available, such as the chemical shifts, shift anisotropies and J-couplings. This is then extended to the characterization of paramagnetic transition-metal cyanides, where strong electron-nuclear interactions are shown to significantly increase spin-lattice relaxation rates allowing the acquisition of spectra without the need of typically employed enhancement techniques, yet often yielding spectra of better quality. Variable-temperature experiments allow a measure of the electron-nuclear interaction, which can be related to spatial proximity, and provide “diamagnetic” chemical shifts allowing comparison with other cyanides. J-couplings and chemical shift anisotropies are shown to be applicable in much the same fashion as with diamagnetic systems.

Solid-State NMR

Glasses

Cyanides

MQMAS

Nuclear Waste

Magic-angle spinning

Multinuclear magnetic resonance investigations of structure and order in borates and metal cyanides

Aguiar, Pedro Miguel

14 September 2007

The local information provided by nuclear magnetic resonance (NMR) makes it an ideal method for the structural investigations of materials lacking extended long-range ordering. This work focuses on investigations of two types of materials possessing very different types of disorder. The first section involves investigations of alkali borate glasses and the application of solid-state NMR techniques to probe short- and medium-range ordering in such glasses. Differences between the various alkali borates over a wide compositional range are probed using one and two-dimensional techniques. The use of double-resonance dipolar recoupling techniques to investigate cesium-boron distances is investigated. The second section probes a series of transition-metal cyanide coordination polymers. The bidentate nature of the cyanide ligand allows for the possibility of forming numerous isomers. Information about the isomer(s) present is gained via the various NMR parameters available, such as the chemical shifts, shift anisotropies and J-couplings. This is then extended to the characterization of paramagnetic transition-metal cyanides, where strong electron-nuclear interactions are shown to significantly increase spin-lattice relaxation rates allowing the acquisition of spectra without the need of typically employed enhancement techniques, yet often yielding spectra of better quality. Variable-temperature experiments allow a measure of the electron-nuclear interaction, which can be related to spatial proximity, and provide “diamagnetic” chemical shifts allowing comparison with other cyanides. J-couplings and chemical shift anisotropies are shown to be applicable in much the same fashion as with diamagnetic systems.

Solid-State NMR

Glasses

Cyanides

MQMAS

Nuclear Waste

Magic-angle spinning