Multinuclear Solid-State Magnetic Resonance Studies on ‘Exotic’ Quadrupolar Nuclei: Acquisition Methods, High-Order Effects, Quantum Chemical Computations, and NMR Crystallography

Widdifield, Cory

05 March 2012

This dissertation attempts to extend the classes of halogen-containing systems which may be studied using solid-state nuclear magnetic resonance (SSNMR). As line shape broadening due to the quadrupolar interaction (QI) scales inversely with the applied field, high-field magnet technology is indispensable for this research. Combining advanced radiofrequency pulse sequences with high-field wideline data acquisition allowed for the collection of very broad SSNMR signals of all quadrupolar halogen nuclei (i.e., 35/37Cl, 79/81Br and 127I) within a reasonable amount of experimental time. The initial systems for study were of the MX2 variety (M = Mg, Ca, Sr, Ba; X = Cl, Br, I). In total, 9 anhydrous compounds were tested. The effects of hydrate formation were tested on 7 additional compounds. Systematic trends in the observed δiso values (and to a lesser extent, Ω and CQ) were found to be diagnostic of the extent of hydration in these materials. Resolving power was successfully tested using SrBr2, which possesses 4 magnetically unique sites. The composition of CaBr2•xH2O was convincingly determined using SSNMR data and the hydration trends noted above. The sensitivity of the QI to the local bonding environment (e.g., bond distance changes of less than 0.05 Å) was used to refine (when coupled with gauge-including projector augmented-wave density functional theory (GIPAW DFT) quantum chemical computations) the structure of MgBr2, and was used to correct prior NMR data for CaCl2 (earlier accounts had been performed upon a CaCl2 hydrate). During NMR data analysis of certain iodine-containing materials, it was found that standard fitting software (which uses perturbation theory) could not reproduce the observations. Proper analysis required the use of exact simulation software and allowed for the observation of high-order quadrupole-induced effects (HOQIE). This motivated further studies using rhenium-185/187 nuclei, where it was expected that HOQIE would be more dramatic. The observed rhenium SSNMR spectra possessed additional fine structure that had never been observed before experimentally, nor would be expected from currently-available perturbation theory analysis software. Lastly, preliminary results are shown where 127I SSNMR is used to study important supramolecular systems, and the composition of the popular synthetic reagent ‘GaI’ is elucidated.

NMR

HOQIE

NMR Crystallography

quadrupoles

quadrupolar nuclei

halogen

chlorine

bromine

iodine

rhenium

GaI

electric field gradient

35Cl

79Br

81Br

127I

185Re

187Re

37Cl

43Ca

25Mg

Multinuclear Solid-State Magnetic Resonance Studies on ‘Exotic’ Quadrupolar Nuclei: Acquisition Methods, High-Order Effects, Quantum Chemical Computations, and NMR Crystallography

Widdifield, Cory

05 March 2012

This dissertation attempts to extend the classes of halogen-containing systems which may be studied using solid-state nuclear magnetic resonance (SSNMR). As line shape broadening due to the quadrupolar interaction (QI) scales inversely with the applied field, high-field magnet technology is indispensable for this research. Combining advanced radiofrequency pulse sequences with high-field wideline data acquisition allowed for the collection of very broad SSNMR signals of all quadrupolar halogen nuclei (i.e., 35/37Cl, 79/81Br and 127I) within a reasonable amount of experimental time. The initial systems for study were of the MX2 variety (M = Mg, Ca, Sr, Ba; X = Cl, Br, I). In total, 9 anhydrous compounds were tested. The effects of hydrate formation were tested on 7 additional compounds. Systematic trends in the observed δiso values (and to a lesser extent, Ω and CQ) were found to be diagnostic of the extent of hydration in these materials. Resolving power was successfully tested using SrBr2, which possesses 4 magnetically unique sites. The composition of CaBr2•xH2O was convincingly determined using SSNMR data and the hydration trends noted above. The sensitivity of the QI to the local bonding environment (e.g., bond distance changes of less than 0.05 Å) was used to refine (when coupled with gauge-including projector augmented-wave density functional theory (GIPAW DFT) quantum chemical computations) the structure of MgBr2, and was used to correct prior NMR data for CaCl2 (earlier accounts had been performed upon a CaCl2 hydrate). During NMR data analysis of certain iodine-containing materials, it was found that standard fitting software (which uses perturbation theory) could not reproduce the observations. Proper analysis required the use of exact simulation software and allowed for the observation of high-order quadrupole-induced effects (HOQIE). This motivated further studies using rhenium-185/187 nuclei, where it was expected that HOQIE would be more dramatic. The observed rhenium SSNMR spectra possessed additional fine structure that had never been observed before experimentally, nor would be expected from currently-available perturbation theory analysis software. Lastly, preliminary results are shown where 127I SSNMR is used to study important supramolecular systems, and the composition of the popular synthetic reagent ‘GaI’ is elucidated.

NMR

HOQIE

NMR Crystallography

quadrupoles

quadrupolar nuclei

halogen

chlorine

bromine

iodine

rhenium

GaI

electric field gradient

35Cl

79Br

81Br

127I

185Re

187Re

37Cl

43Ca

25Mg

Multinuclear Solid-State Magnetic Resonance Studies on ‘Exotic’ Quadrupolar Nuclei: Acquisition Methods, High-Order Effects, Quantum Chemical Computations, and NMR Crystallography

Widdifield, Cory

05 March 2012

This dissertation attempts to extend the classes of halogen-containing systems which may be studied using solid-state nuclear magnetic resonance (SSNMR). As line shape broadening due to the quadrupolar interaction (QI) scales inversely with the applied field, high-field magnet technology is indispensable for this research. Combining advanced radiofrequency pulse sequences with high-field wideline data acquisition allowed for the collection of very broad SSNMR signals of all quadrupolar halogen nuclei (i.e., 35/37Cl, 79/81Br and 127I) within a reasonable amount of experimental time. The initial systems for study were of the MX2 variety (M = Mg, Ca, Sr, Ba; X = Cl, Br, I). In total, 9 anhydrous compounds were tested. The effects of hydrate formation were tested on 7 additional compounds. Systematic trends in the observed δiso values (and to a lesser extent, Ω and CQ) were found to be diagnostic of the extent of hydration in these materials. Resolving power was successfully tested using SrBr2, which possesses 4 magnetically unique sites. The composition of CaBr2•xH2O was convincingly determined using SSNMR data and the hydration trends noted above. The sensitivity of the QI to the local bonding environment (e.g., bond distance changes of less than 0.05 Å) was used to refine (when coupled with gauge-including projector augmented-wave density functional theory (GIPAW DFT) quantum chemical computations) the structure of MgBr2, and was used to correct prior NMR data for CaCl2 (earlier accounts had been performed upon a CaCl2 hydrate). During NMR data analysis of certain iodine-containing materials, it was found that standard fitting software (which uses perturbation theory) could not reproduce the observations. Proper analysis required the use of exact simulation software and allowed for the observation of high-order quadrupole-induced effects (HOQIE). This motivated further studies using rhenium-185/187 nuclei, where it was expected that HOQIE would be more dramatic. The observed rhenium SSNMR spectra possessed additional fine structure that had never been observed before experimentally, nor would be expected from currently-available perturbation theory analysis software. Lastly, preliminary results are shown where 127I SSNMR is used to study important supramolecular systems, and the composition of the popular synthetic reagent ‘GaI’ is elucidated.

NMR

HOQIE

NMR Crystallography

quadrupoles

quadrupolar nuclei

halogen

chlorine

bromine

iodine

rhenium

GaI

electric field gradient

35Cl

79Br

81Br

127I

185Re

187Re

37Cl

43Ca

25Mg

Multinuclear Solid-State Magnetic Resonance Studies on ‘Exotic’ Quadrupolar Nuclei: Acquisition Methods, High-Order Effects, Quantum Chemical Computations, and NMR Crystallography

Widdifield, Cory

January 2012

This dissertation attempts to extend the classes of halogen-containing systems which may be studied using solid-state nuclear magnetic resonance (SSNMR). As line shape broadening due to the quadrupolar interaction (QI) scales inversely with the applied field, high-field magnet technology is indispensable for this research. Combining advanced radiofrequency pulse sequences with high-field wideline data acquisition allowed for the collection of very broad SSNMR signals of all quadrupolar halogen nuclei (i.e., 35/37Cl, 79/81Br and 127I) within a reasonable amount of experimental time. The initial systems for study were of the MX2 variety (M = Mg, Ca, Sr, Ba; X = Cl, Br, I). In total, 9 anhydrous compounds were tested. The effects of hydrate formation were tested on 7 additional compounds. Systematic trends in the observed δiso values (and to a lesser extent, Ω and CQ) were found to be diagnostic of the extent of hydration in these materials. Resolving power was successfully tested using SrBr2, which possesses 4 magnetically unique sites. The composition of CaBr2•xH2O was convincingly determined using SSNMR data and the hydration trends noted above. The sensitivity of the QI to the local bonding environment (e.g., bond distance changes of less than 0.05 Å) was used to refine (when coupled with gauge-including projector augmented-wave density functional theory (GIPAW DFT) quantum chemical computations) the structure of MgBr2, and was used to correct prior NMR data for CaCl2 (earlier accounts had been performed upon a CaCl2 hydrate). During NMR data analysis of certain iodine-containing materials, it was found that standard fitting software (which uses perturbation theory) could not reproduce the observations. Proper analysis required the use of exact simulation software and allowed for the observation of high-order quadrupole-induced effects (HOQIE). This motivated further studies using rhenium-185/187 nuclei, where it was expected that HOQIE would be more dramatic. The observed rhenium SSNMR spectra possessed additional fine structure that had never been observed before experimentally, nor would be expected from currently-available perturbation theory analysis software. Lastly, preliminary results are shown where 127I SSNMR is used to study important supramolecular systems, and the composition of the popular synthetic reagent ‘GaI’ is elucidated.

NMR

HOQIE

NMR Crystallography

quadrupoles

quadrupolar nuclei

halogen

chlorine

bromine

iodine

rhenium

GaI

electric field gradient

35Cl

79Br

81Br

127I

185Re

187Re

37Cl

43Ca

25Mg

Physico-Chemical Characterisation of Chloride Transmembrane Transport using Calix[6]arene-based Receptors

Grauwels, Glenn

20 August 2020

The development of synthetic molecular receptors that can selectively bind anions, translocate them through a lipidic bilayer membrane and release them on the other side is a very topical and emerging field of supramolecular chemistry, warranted by the biological importance of transmembrane anion transport.The first part of this thesis is devoted to the study of the transmembrane transport of chloride and of the organic ion pair propylammonium chloride with calix[6]arene receptors functionalized with three (thio)urea arms on their small rim. The transport of chloride across the lipid bilayer of liposomes was monitored by fluorescence spectroscopy using the lucigenin assay. We report the first example of calix[6]arenes able to act as mobile carrier for the transport of chloride via a Cl-/NO3- antiport. We furthermore show that our calixarene systems are able to perform the cotransport of propylammonium chloride, with the chloride bound at the level of the (thio)urea groups and the ammonium included in the calixarene cavity. To provide direct proof of cotransport, we developed a 1H NMR methodology involving a thulium- complex shift reagent with which we were able to distinguish the signals of the ammonium transported inside the liposomes from those of the external ammonium. We also highlight the role of the complexing calixarene cavity for the cotransport by comparing the calixarenes to known transporters deprived of a cavity. The transmembrane transport organic ion pairs could find applications in the transport of biologically relevant ammonium compounds such as catecholamines and amino acids. Our results are reported in the publication “Repositioning Chloride Transmembrane Transporters: Transport of Organic Ion Pairs” Grauwels, G. Valkenier, H. Davis, A. P. Jabin, I. Bartik, K. Angew. Chemie - Int. Ed. 2019, 58, 6921–6925.The second part of this thesis is devoted to the study of binding of chloride to receptors embedded in a lipid membrane, the first step of the transmembrane transport process. Both 1H and 31P NMR spectroscopy proved to be inadequate to study the binding using liposomes or micelles as model membranes. With liposomes, the NMR signals are too broad to be exploited and in the case of micelles, the competition between the lipid headgroups and chloride made it impossible to obtain a NMR signature which unambiguously characterizes chloride binding. The 35Cl NMR signal is on the other hand strongly affected by the presence of anion receptors, both in organic solvents and when incorporated lipid bilayers. We developed a methodology to evaluate the binding of chloride, based on the monitoring of the chloride linewidth during titration experiments. A linear relationship between the linewidth and the concentration of receptors is observed and the slopes can be exploited to compare the binding strengths of different structurally related receptors. We show that 35/37Cl NMR is a versatile tool which can help in the understanding and development of new transporters by providing new insights of the physicochemical understanding of the transport process. / Doctorat en Sciences de l'ingénieur et technologie / info:eu-repo/semantics/nonPublished

Chimie

Chimie des colloïdes

Chimie organique

Physico-chimie générale

Biophysique

Biochimie

Supramolecular chemistry

transmembrane transport

liposomes

calix[6]arenes

shift reagents

anion binding

35Cl NMR