Rare earth doped fluorophosphate glass and glass-ceramics: structure-property relations / Vidros e vitroceramicas dopados com terras raras: correlações entre estrutura e propriedades

Tássia de Souza Gonçalves

03 September 2018

Rare earth RE3+ doped fluorophosphates glasses and glass ceramics are among the most promising candidates for high efficiency laser generation in the near-infrared spectral region. Glass ceramics are polycrystalline materials of fine microstructure that are produced by the controlled crystallization (devitrification) of a glass. By developing fluorophosphate base glasses with appropriate compositions and by controlling crystal nucleation and growth in them, glass ceramics with special properties can be fabricated combining the advantages of fluorides (low phonon energy, low refractive indexes, extensive optical window, lower hygroscopicity) and oxides (high chemical and mechanical stability and high dopant solubility), resulting in enhancement of the RE3+ emissive properties. In this study, we present the synthesis by melting/quenting and structural/spectroscopic investigation of new glasses and glass ceramics with composition 25BaF225SrF2(30-x)Al(PO3)3xAlF3(20-z)YF3: zREF3, where x = 15, 20 or 25, RE = Er3+ an/or Yb3+ and Nd3+. A detailed structural investigation of a series of this glasses has been conducted, using Raman, solid-state nuclear magnetic resonance (NMR) and electron paramagnetic resonance (EPR) spectroscopies. / Vidros e vitrocerâmicas fluorofosfatos dopados com íons terras raras (TR3+) estão entre os candidatos mais promissores para a geração de laser de alta eficiência na região espectral do infravermelho próximo. As vitrocerâmicas são materiais policristalinos com microestrutura bem definida obtida a partir da cristalização controlada do vidro base. Desenvolvendo vidros base de fluorofosfato com composições apropriadas e controlando a nucleação e crescimento de cristais, vitrocerâmicas com propriedades especiais podem ser fabricadas combinando as vantagens dos fluoretos (baixa energia de fônons, baixos índices de refração, janela ótica extensa, baixa higroscopicidade) e óxidos (alta estabilidade química e mecânica e alta solubilidade dopante), resultando no aumento das propriedades emissoras dos íons TR3+. Neste estudo, apresentamos a síntese por fusão/resfriamento e investigação estrutural/espectroscópica de novos vidros e vitrocerâmicas com composição 25BaF225SrF2(30-x)Al(PO3)3xAlF3(20-z)YF3: zREF3, onde x = 15, 20 ou 25, RE = Er3+ an / ou Yb3+ e Nd3+. Uma investigação estrutural detalhada de uma série destes vidros foi conduzida utilizando espectroscopias Raman, de ressonância magnética nuclear de estado sólido (RMN) e de ressonância paramagnética eletrônica (EPR).

Espectroscopia UV-VIS

Íons terras raras

RMN

Vidros fluorofosfatos

Fluorophosphate glasses

NMR

Rare earth ions

UV-VIS spectroscopy

Sensor óptico de temperatura baseado no processo de conversão ascendente de energia em vidros fluorofosfatos dopados com Er3+ / Optical temperature sensor based on upconversion in fluorophosphate glasses doped with Er3+

Allysonn Jorge dos Santos

12 February 2016

O processo de conversão ascendente de energia (infravermelho ao visível) é amplamente estudado em materiais dopados com íons terras raras trivalentes (TR3+) devido as várias possibilidades de aplicações tecnológicas. Tal processo consiste na emissão de fótons de maior energia (usualmente no visível) mediante excitação com fótons de menor energia (infravermelho) via mecanismo de absorção de dois fótons e/ou transferência de energia entre os íons TR3+. Entre os materiais estudados destacam-se vidros e vitrocerâmicas dopados com Er3+ com emissões nas regiões do verde e do vermelho, que podem ser eficientemente excitadas por lasers de diodo na região do infravermelho próximo (980 nm). Uma das aplicações possíveis para este processo é a de um sensor óptico de temperatura baseado na dependência da razão de intensidades de emissão dos níveis 2H11/2 e 4S3/2 do Er3+ com a temperatura, vantajoso para operação em ambientes hostis como transformadores de alta tensão, em processos industriais, etc. Como a eficiência das emissões depende também da matriz hospedeira, os vidros fluorofosfatos com composição 25BaF225SrF2(30-x)Al(PO3)3xAlF3(20-z)YF3:zErF3 com x = 20 e z = 1,0 a 5,0 mol% foram escolhidos por apresentarem alta estabilidade química e mecânica, e energia de fônon relativamente baixa. Assim, amostras vítreas dopadas com várias concentrações de Er3+ foram previamente caracterizadas e selecionadas para desenvolver o protótipo que emprega a variação de intensidade relativa das emissões 2H11/2 → 4I15/2 e 4S3/2 → 4I15/2 do vidro fluorofosfato dopado com Er3+ na medição de temperaturas. Este protótipo apresenta as características de baixo custo, alta sensibilidade e rápida resposta. / The infrared-to-visible upconversion process is widely studied in materials doped with trivalent rare earth ions (RE3+) due to the various possibilities of technological applications. The process is based on the emission of photons with higher energy (in the visible) than the excitation photons (in the infrared) via the mechanisms of two-photon absorption and/or energy transfer between RE3+ ions. Among the studied materials emphasis is given to glasses and glass ceramics doped with Er3+, exhibiting intense emissions in the green and red, which can be efficiently excited by diode lasers in the near infrared region (980 nm). One application of this process is an optical temperature sensor based on the dependence of the ratio of the emission intensities of levels 2H11/2 and 4S3/2 of Er3+ on the temperature of the sample. Such sensor would be advantageous for operation in hostile environments, such as high voltage transformers, industrial processes, etc. Because the efficiency of upconversion also depends on the host matrix composition, flurophosphate glasses are interesting candidates due to their high chemical stability, good mechanical properties and relatively low phonon energy. Glasses with composition 25BaF225SrF2(30-x)Al(PO3)3xAlF3(20-z)YF3:zErF3 with x = 20 and z varying from 1.0 to 5.0 mol% were characterized and selected to develop the prototype employing the fluorescence of fluorophosphate glass doped with Er3+ for measuring temperatures with the following characteristics: low cost, high accuracy and fast response.

Conversão ascendente

Íons terras raras

Sensor de temperatura

Vidros fluorofosfatos

Fluorophosphate glasses

Rare earth ions

Temperature sensor

Upconversion

A Multinuclear Magnetic Resonance Study of Alkali Ion Battery Cathode Materials

Hurst, Chelsey

January 2019

The need for highly efficient energy storage devices has been steadily increasing due to growing energy demands. Research in electrochemical energy storage in the form of batteries has consequently become crucial. Currently, the most commercialized battery technology is the lithium ion battery (LIB). Concerns over the relatively limited global lithium supply, however, have led to the development of sodium ion batteries (SIBs). Solid-state nuclear magnetic resonance (ssNMR) spectroscopy is an ideal technique for analyzing battery materials as it can potentially distinguish between different ions within the material. The most typical cathode for commercial LIBs are the family of NMC layered oxides with the general form Li[NixMnyCo1-x-y]O2, which consist of Li layers between sheets of transition metals (TMs). The pj-MATPASS NMR technique, in conjunction with Monte Carlo simulations, was applied to investigate the ionic arrangement within TM layers of NMC622 (Li[Ni0.6Mn0.2Co0.2]O2), which revealed the presence of ion clustering in the pristine form of this material. This thesis also investigated the promising SIB cathode, Na3V2(PO4)2F3 (NVPF). NVPF has the capability to produce energy densities comparable to those of LIBs and is well understood from a structural standpoint, however ion dynamics within the material are still undetermined. A series of materials have, therefore, been synthesized with the general form, Na3V2-xGax(PO4)2F3 (where x = 0, 1, and 2), where diamagnetic Ga3+ was introduced into the structure to enable the establishment of a structural correlation with observed Na-ion dynamics. It, therefore, became possible to explore ionic site exchange using 23Na ssNMR. Density functional theory (DFT) calculations have also been performed alongside ssNMR to confirm chemical shift assignments and provide structural insight. Additionally, electron paramagnetic resonance (EPR) spectroscopy was also used to investigate the paramagnetic nature of NVPF and its variants. Insights into the ionic arrangement and very fast Na-ion dynamics within these materials were revealed. / Thesis / Master of Science (MSc) / The need for highly efficient energy storage devices, especially in the form of batteries, has been steadily increasing due to growing energy demands. Presently, the most commercialized types of batteries are lithium ion batteries (LIBs). Concerns over the relatively limited global lithium supply, however, have led to the development of sodium ion battery (SIB) alternatives. Various solid-state nuclear magnetic resonance (ssNMR) techniques have been employed in this thesis to investigate both LIB and SIB cathode materials. The LIB cathode Li[Ni0.6Mn0.2Co0.2]O2 was examined with a combination of ssNMR and Monte Carlo simulations, and it was found that ion clustering occurs in the pristine form of these materials. The promising family of SIB cathodes, Na3V2-xGax(PO4)2F3, was studied by a combination of ssNMR, ab initio calculations, and EPR, which allowed for a correlation to be established between the crystal structure and the fast ion dynamics within these materials.

Solid-state NMR

Sodium ion batteries

Lithium ion batteries

Cathode materials

Sodium vanadium fluorophosphate

Density functional theory calculations

Monte carlo calculations

NMC622

NMC

Two dimensional exchange spectroscopy

The Fate and Transport of Chemical Warfare Agent Simulants in Complex Matrices

Daphney, Cedrick M.,

15 July 2008

Experiments to determine the fate and transport of the chemical warfare agent (CWA) simulants diisopropyl fluorophosphate (DIFP), O,S-diethyl methylphosphonothioate (OSDEMP), and 2-Chloroethyl ethyl sulfide (CEES) exposed to complex matrix systems are reported here. The aforementioned simulants were used in place of O-isopropyl methylphosphonofluoridate (GB), O-Ethyl S-(2-diisopropylaminoethyl) methylphosphonothiolate (VX), and Bis (2-chloroethyl) sulfide (HD), respectively. At ambient temperature, simulant pH (2.63 to 12.01) and reaction time (1 minute to 24 hours) were found to have significant influence on the recovery of simulants from charcoal, plastic, and TAP (butyl rubber gloves) in aqueous media. Buffer systems used included, phosphate, acetate, borate, and disodium tetraborate. Organic extractions were carried out using a 90:10 (v/v) dichloromethane / 2-propanol solution. All extracts were analyzed with a gas chromatograph equipped with flame ionization and flame photometric detectors (GC-FID-FPD). The FPD was used to determine the amount of simulant recovery.

O-isopropyl methylphosphonofluoridate

Bis (2-chloroethyl) sulfide

Gas chromatography

Flame ionization detector

flame photometric detector

Demilitarization

Chemical demilitarization facilities

2-chloroethyl ethylsulfide

O-S-diethyl methylphosphonothioate

Diisopropyl fluorophosphate

Chemical warfare agents

Nouveaux fluorophosphates de métaux de transition utilisés comme matériaux d'électrode positive pour batteries li-ion / New Transition Metal Fluorophosphates as Positive Electrode Materials for Li-ion Batteries

Ateba Mba, Jean-Marcel

04 October 2013

Nos efforts se sont portés sur des fluorophosphates de structure TAVORITE de formule LiMPO4F (M = V, Fe, Ti) et LiVPO4O qui, comparés à d’autres familles structurales de phosphates tels que Li3M2(PO4)3 (NASICON) ou LiFePO4(OH) (Tavorite) possèdent d’excellentes densités d’énergie théorique comme matériaux d’électrodes dans des accumulateurs au Li. Des méthodes de synthèse reproductibles, par voie céramique en tubes scellés et/ou ionothermale (synthèse à basse température), ont été mises au point dans ce travail. Les matériaux ainsi préparés ont été caractérisés en détail par magnétométrie, par RMN et surtout par diffraction des rayons X et des neutrons. Les structures cristallines ont ainsi pu être déterminées ainsi que les mécanismes d’insertion/extraction du Li+, via de nombreuses études par diffraction X insitu lors de la charge/décharge des accumulateurs. / This work focused on TAVORITE-based fluorophosphates LiMPO4F (M = V, Fe, Ti) and LiVPO4O which, when compared with other phosphate structural families such as Li3V2(PO4)3 (NASICON) or LiFePO4(OH) (Tavorite), possess superior energy density as electrode materials for Li batteries. Reproducible synthesis procedures were developed through “classical” ceramic routes in sealed containers and/or low temperature ionothermal reaction. The obtained materials were characterized by magnetometry, solid state NMR and heavily by X-Ray and Neutron diffraction. The crystal structures of all the materials were determined, as well as the mechanisms of Li+ insertion/extraction through insitu X-Ray diffraction during electrochemical charge/discharge of the batteries.

Diffraction des rayons X et des neutrons

Diffraction X in situ

Fluorophosphates

Tavorite

Densités d’énergie

Positive electrode for Li-ion batteries

X-ray and neutron diffraction

In-situ X-ray diffraction

Fluorophosphate

Tavorite

Energy density

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