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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

The Analysis of Decavanadates and Their Transport Through the Environment using 51V NMR

Smiley, Samuel James 01 December 2019 (has links)
No description available.
2

Equilibrium and structure studies of aqueous vanadophosphates and molybdovanadophosphates

Selling, Anna January 1996 (has links)
<p>Diss. (sammanfattning) Umeå : Umeå universitet, 1996, härtill 4 uppsatser</p> / digitalisering@umu
3

Vanadate and Peroxovanadate Complexes of Biomedical Relevance : A speciation approach with focus on diabetes

Gorzsás, András January 2005 (has links)
<p>Diabetes mellitus is one of the most threatening epidemics of modern times with rapidly increasing incidence. Vanadium and peroxovanadium compounds have been shown to exert insulin–like actions and, in contrast to insulin, are orally applicable. However, problems with side–effects and toxicity remain. The exact mechanism(s) by which these compounds act are not yet fully known. Thus, a better understanding of the aqueous chemistry of vanadates and peroxovanadates in the presence of various (bio)ligands is needed.</p><p>The present thesis summarises six papers dealing mainly with aqueous speciation in different vanadate – and peroxovanadate – ligand systems of biological and medical relevance. Altogether, five ligands have been studied, including important blood constituents (lactate, citrate and phosphate), a potential drug candidate (picolinic acid), and a dipeptide (alanyl serine) to model the interaction of (peroxo)vanadate in the active site of enzymes. Since all five ligands have been studied both with vanadates and peroxovanadates, the number of systems described in the present work is eleven, including the vanadate – citrate – lactate mixed ligand system. The pH–independent formation constants have been determined for 33 ternary vanadate – ligand, 41 quaternary peroxovanadate – ligand and two vanadate – mixed ligand species in addition to the p<i>K</i><sub>a</sub> values of all five ligands. These constants have been used to model physiological conditions, and the biomedical relevance of the different species is discussed.</p><p>The studies have been performed at 25 ºC in the physiological medium of 0.150 M Na(Cl), i.e. the ionic strength of human blood. No buffers have been used, and wide pH–ranges have usually been covered. The applied experimental techniques comprise mostly <sup>51</sup>V NMR and potentiometry, but <sup>31</sup>P, <sup>13</sup>C, <sup>1</sup>H and <sup>14</sup>N NMR as well as EPR and ESI–MS have also been used to gain additional information. Multimethod data have been treated by the least–squares program LAKE and modelling has been carried out by the software package WinSGW.</p><p>Whenever possible, solution structures of the species have been proposed. In addition, simple biological tests have been carried out to determine the stability of the formed peroxovanadate complexes in the presence of human catalase. A brief comparison is given of the different vanadate – ligand and peroxovanadate – ligand systems with emphasis on observed trends and general features.</p>
4

Vanadate and Peroxovanadate Complexes of Biomedical Relevance : A speciation approach with focus on diabetes

Gorzsás, András January 2005 (has links)
Diabetes mellitus is one of the most threatening epidemics of modern times with rapidly increasing incidence. Vanadium and peroxovanadium compounds have been shown to exert insulin–like actions and, in contrast to insulin, are orally applicable. However, problems with side–effects and toxicity remain. The exact mechanism(s) by which these compounds act are not yet fully known. Thus, a better understanding of the aqueous chemistry of vanadates and peroxovanadates in the presence of various (bio)ligands is needed. The present thesis summarises six papers dealing mainly with aqueous speciation in different vanadate – and peroxovanadate – ligand systems of biological and medical relevance. Altogether, five ligands have been studied, including important blood constituents (lactate, citrate and phosphate), a potential drug candidate (picolinic acid), and a dipeptide (alanyl serine) to model the interaction of (peroxo)vanadate in the active site of enzymes. Since all five ligands have been studied both with vanadates and peroxovanadates, the number of systems described in the present work is eleven, including the vanadate – citrate – lactate mixed ligand system. The pH–independent formation constants have been determined for 33 ternary vanadate – ligand, 41 quaternary peroxovanadate – ligand and two vanadate – mixed ligand species in addition to the pKa values of all five ligands. These constants have been used to model physiological conditions, and the biomedical relevance of the different species is discussed. The studies have been performed at 25 ºC in the physiological medium of 0.150 M Na(Cl), i.e. the ionic strength of human blood. No buffers have been used, and wide pH–ranges have usually been covered. The applied experimental techniques comprise mostly 51V NMR and potentiometry, but 31P, 13C, 1H and 14N NMR as well as EPR and ESI–MS have also been used to gain additional information. Multimethod data have been treated by the least–squares program LAKE and modelling has been carried out by the software package WinSGW. Whenever possible, solution structures of the species have been proposed. In addition, simple biological tests have been carried out to determine the stability of the formed peroxovanadate complexes in the presence of human catalase. A brief comparison is given of the different vanadate – ligand and peroxovanadate – ligand systems with emphasis on observed trends and general features.
5

Síntese e caracterização espectroscópica de novos vanadosilicatos utilizando templates orgânicos derivados de piperidinas / Syntheses and spectroscopic characterization of new vanadosilicates using organic templates derivatives of piperidines

Contro, Janine [UNESP] 11 March 2016 (has links)
Submitted by Janine Contro null (janinecontro@yahoo.com.br) on 2016-04-07T18:56:18Z No. of bitstreams: 1 DISSERTAÇÃO - JANINE.pdf: 7764303 bytes, checksum: a8fc2422ef9a7fc1ce8eef29ce54e487 (MD5) / Approved for entry into archive by Felipe Augusto Arakaki (arakaki@reitoria.unesp.br) on 2016-04-08T12:32:48Z (GMT) No. of bitstreams: 1 contro_j_me_sjrp.pdf: 7764303 bytes, checksum: a8fc2422ef9a7fc1ce8eef29ce54e487 (MD5) / Made available in DSpace on 2016-04-08T12:32:48Z (GMT). No. of bitstreams: 1 contro_j_me_sjrp.pdf: 7764303 bytes, checksum: a8fc2422ef9a7fc1ce8eef29ce54e487 (MD5) Previous issue date: 2016-03-11 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Foram sintetizados neste trabalho novos vanadosilicatos, para suas sínteses foram utilizadas moléculas orgânicas derivadas de 3,5-dimetilpiperidina (SDAs 1 – 4) e 2,6-dimetilpiperidina (SDAs 5 – 8) em sua mistura reacional. Os vanadosilicatos foram nomeados seguindo a numeração dos SDAs utilizados em suas sínteses (VN1 a VN8). As caracterizações físico-químicas dos vanadosilicatos foram realizadas utilizando-se técnicas como difração de raios-X (DRX), microscopia eletrônica de varredura (MEV), espectroscopia no infravermelho (FT-IR), espectroscopia Raman, espectroscopia no UV – Visível e ressonância magnética nuclear com rotação em torno do ângulo mágico (RMN-MAS) no estado sólido para os núcleos de 13C, 29Si e 51V. Os resultados experimentais indicam que as moléculas orgânicas podem atuar como agentes direcionadores de estrutura (SDAs). Os SDAs 1, 3, 4 e 5 direcionaram a formação dos vanadosilicatos VN1, VN3, VN4 e VN5 isomorfos ao titaniosilicato ETS-10 e ao vanadosilicato do tipo AM-6, enquanto os SDAs 2, 6, 7 e 8 direcionam a estrutura de novos vanadosilicatos (VN2, VN6, VN7 e VN8). Evidências experimentais da incorporação de vanádio na estrutura cristalina dos materiais foram obtidas por FT-IR, UV – Visível, 29Si RMN-MAS. Na espectroscopia no infravermelho (FT-IR) o sinal localizado na frequência 870 cm-1 é proveniente da vibração da ligação V-O e o sinal centrado na frequência 1030 cm-1 é proveniente da vibração dos grupos vanadila. Na espectroscopia no UV – Visível o comprimento de onda 600 nm representa os grupos vanadila e os comprimentos onda 450 e 545 nm indicam a presença de vanádios em coordenação octaédrica distorcida (VN2) e ordenada (VN1, VN3 e VN4), respectivamente. E no caso do RMN de 29Si o sinal centralizado em -93 ppm é proveniente de núcleos de silício da forma Si(3Si, 1V), estes dados comprovam a incorporação do vanádio na rede cristalográfica do material microporoso. A espectroscopia no UV – Visível juntamente com a ressonância magnética nuclear de 29Si sugerem que os vanadosilicatos isomorfos ao titaniosilicato VN1, VN3, VN4 e VN5 apresentam uma rede cristalográfica mais ordenada que os vanadosilicatos VN2, VN6, VN7 e VN8. Visto que a espectroscopia no UV – Visível indica que os octaedros VO6 dos vanadosilicatos isomorfos ao ETS-10 são mais regulares que os octaedros de vanádio dos novos vanadosilicatos, e os resultados experimentais de RMN-MAS de 29Si revelam que os vanadosilicatos isomorfos ao ETS-10 apresentam somente o sinal centralizado em -93 ppm, proveniente de núcleos de silício da forma Si(3Si, 1V), enquanto os novos vanadosilicatos apresentam, além do sinal centralizado em -93 ppm, um novo sinal centralizado em -110 ppm, proveniente de núcleos de silício da forma Si(4Si, 0V). / New vanadosilicates were synthesized in this work. They have been synthesized using organic molecules derivatives of 3,5-dimethylpiperidine (SDAs 1 – 4) and 2,6-dimethylpiperidine (SDAs 5 – 8) in their reactional mixture. The vanadosilicates were named using the same numbers of the SDA used in their synthesis (VN1 to VN8). Physicochemical characterization of the new vanadosilicates was carried out by X-ray diffraction (XRD), scanning electron microscopy (SEM), infrared spectroscopy (FT-IR), Raman spectroscopy, UV – Visible spectroscopy (UV – Vis), solid state 13C, 29Si and 51V magic angle spinning nuclear magnetic resonance (MAS NMR) spectroscopy. The experimental results suggest that the organic molecules can act as structure directing agents (SDAs). The SDAs 1, 3, 4 and 5 directed the synthesis to the formation of vanadosilicates VN1, VN3, VN4 and VN5 isomorphs to titanosilicate ETS-10 and vanadosilicate AM-6; on the other hand the SDAs 2, 6, 7 and 8 show selectivity to the formation of new vanadosilicates (VN2, VN6, VN7 and VN8). Experimental evidences of the vanadium incorporation into the vanadosilicate framework were obtained by FT-IR, UV – Vis and 29Si MAS NMR. The infrared spectroscopy has a signal at the frequency of 870 cm-1 designed to the vibration of V-O bond and the signal at the frequency of 1030 cm-1 designed to the vibration of vanadyl groups. The UV – Vis spectroscopy reveals the presence of vanadyl groups at 600 nm and the wavelengths 450 and 545 nm indicate the presence of distorted (VN2) and ordely (VN1, VN3 and VN4) octahedrally coordinated vanadium, respectively. And the 29Si MAS NMR shows a chemical shift centred at -93 ppm assigned to the Si(3Si, 1V) neighbourhood. UV – Vis spectroscopy and 29Si MAS NMR evidence that the vanadosilicates VN1, VN3, VN4 and VN5, isomorphs to ETS-10, show their framework more crystalline than the new vanadosilicates framework (VN2, VN6, VN7 and VN8). This affirmative is supported by both UV – Vis and 29Si MAS NMR data. UV – Vis data indicates that VO6 octahedra in vanadosilicates isomorphs to ETS- 10 are more regular than the VO6 octahedra in the new vanadosilicates. 29Si MAS NMR experimental data shows that vanadosilicates isomorphs to ETS-10 have only one chemical shift centred at -93 ppm, assigned to the Si(3Si, 1V) neighbourhood, while the new vanadosilicates have two chemical shifts that one centred at -93 ppm and other centred at -110 ppm assigned to Si(4Si, 0V) neighbourhood.

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