Synthesis, characterization, and structural modeling of graphite intercalation compounds with fluoroanions

Yan, Wei

10 December 2004

Graduation date: 2005

Synthesis and structural characterization of graphite intercalation compounds (GICs)

Zhang, Xuerong

06 May 1999

Graduation date: 1999

Estudo em nanocompósitos e eletrólitos poliméricos por ressonância magnética. / Study of nanocomposite and polymer eletrolyte by magnetic resonance

Bloise Junior, Antonio Carlos

21 January 2003

Foram realizadas pesquisas em uma série de condutores iônicos que apresentam aplicações na área dos dispositivos eletroquímicos de estado sólido, utilizando-se basicamente a técnica de Ressonância Magnética Nuclear (RMN). A primeira parte deste trabalho é dedicada aos compostos de intercalação baseados na matriz de dissulfeto de molibdênio (MoS2) onde as espécies intercalantes (íons de lítio e moléculas de aminas) são inseridas num espaço de dimensionalidade reduzida gerado pela matriz. Já a segunda parte envolve os condutores iônicos poliméricos do tipo compósitos, nos quais foram utilizadas nanopartículas de carbono (Carbon Black) e titânio (TiO2) no eletrólito formado pelo poli(óxido de etileno) (POE) e o perclorato de lítio (LiClO4). Todos estes sistemas apresentam, em geral, uma considerável complexidade estrutural, o que significa que os movimentos moleculares e de difusão iônica se produzem num meio semicristalino (caso dos compósitos) ou num meio de dimensionalidade reduzida (caso dos intercalados). A espectroscopia de RMN dos núcleos de 7Li e 1H é uma técnica conveniente para o estudo destes materiais, pois é possível avaliar, através dos resultados obtidos das medidas dos tempos de relaxação e formas de linha, os efeitos provocados pela baixa dimensionalidade dos movimentos em estruturas laminares (caso dos intercalados), bem como identificar e aferir as interações e os mecanismos de relaxação resultantes dos diferentes graus de liberdade dos movimentos (iônicos e moleculares), fornecer parâmetros estruturais (distâncias interatômicas) que auxiliam na proposta de possíveis modelos estruturais e caracterizar completamente a escala temporal dos movimentos iônicos e moleculares. / Nuclear Magnetic Resonance (RMN) techniques were used to study a series of ionic conductor materials, which present applications in the area of the solid-state electrochemical devices. The first part of this work is dedicated to the study of intercalation compounds based on the molybdenum disulfide matrix (MoS2), where the intercalated species (lithium ion and amine molecule) are inserted in the low-dimensionality space generated by the matrix. The second part involves the study of a composite polymer electrolyte, employing fillers like Carbon Black and titanium dioxide (Tio2) nano particles in the electrolyte formed by the poly(ethy1ene oxide) and a lithium salt (LiClO4). In general, these systems present a considerable structural complexity, meaning that the molecular movements and ionic diffusion are produced in a semicrystalline environment (case of the composites) or in an environment of reduced dimensionality (case of intercalates). The 7Li and 1H NMR spectroscopy is a convenient technique for the study of these materials. Relaxation time and line shape measurements may provide a tool to investigate the effects provoked by the low-dimensionality of the movements in laminate structures (case of intercalate), to identify the interactions and relaxation mechanisms of the ionic and molecular motions, to supply structural parameters (interatomic distances) that would help the proposal of possible structural models, and finally, to characterize the time scale of the ionic and molecular movements completely.

Composite polymer electrolyte

Compóstios

Intercalados

Intercalation compounds

NMR

RMN

Surface Electron Dynamics for Intercalated Graphene (and Other 2D Materials) on a Metal Template

Lin, Yi

January 2019

In this dissertation, I report my thesis work on studying surface electron dynamics for intercalated graphene on a metal template using both experimental and theoretical methods. A general description of the research motivation is summarized in the first Chapter. The experimental and theoretical techniques involved in this thesis research are introduced in Chapter 2. In Chapter 3 and Chapter 4, the key findings of this thesis work are reported. These findings concern two novel surface electronic phenomena in oxygen intercalated-graphene on Ir(111) interface. The first phenomenon was the observation of strongly excited image potential states (IPS) in a well-defined quasi-free-standing graphene (QFG) at an oxygen-intercalated Gr/Ir interface. Specifically, the interfaces were synthesized to form Gr/Ir and QFG (Gr/O/Ir) by oxygen intercalation. The syntheses were monitored by low-energy-electron-diffraction (LEED). Our research succeeded in exciting and measuring IPSs on both interfaces by angle-resolved two-photon-photoemission (AR-2PPE) and then the increasing of the IPS binding energy of 0.17 eV following the oxygen intercalation. Finally, our work proposed a theoretical model based on density-functional-theory (DFT) calculations and effective potential models to simulate the surface potential variations in the presence of the intercalated oxygen and its influence on IPSs. The energy shift could be understood by an approximation considering only the out-of-plane chemical and structural modulations. In addition, the results of the model are in strong agreement with the measured IPS band structures. The agreement enables us to attribute the IPS binding energy shift to two potential modulations: a deepened and widened interfacial potential well due to the presence of oxygen intercalants and an increased graphene-Ir interlayer distance. The second phenomenon investigated was a non-dispersive unoccupied band at the Brillouin Zone (BZ) center, which was observed only for Gr/O/Ir but not for Gr/Ir interface. The unoccupied state is approximately 2.6 eV above Fermi energy and was discovered by AR-2PPE. The existence of the non-dispersive band inspired us to undertake a careful examination of the in-plane structural modulation induced by oxygen intercalants. LEED measurements confirm the presence of an in-plane 2$\times$2 periodicity of the intercalated oxygen in QFG. This periodicity can provide periodic perturbation to QFG and can generate the flat unoccupied state due to zone-folding effects from the BZ edge. Angle-resolved photoemission measurements and DFT-based calculations were used to compare the measured Gr/O/Ir states to that of Gr/Ir and O/Ir, providing solid evidence for this zone-folding interpretation. The realization of mixing bands between high symmetry points in BZ by zone-folding in Gr/O/Ir demonstrates a pathway for engineering the graphene electronic structure and its two-photon optical excitation via other ordered intercalants. In addition, a separate but related collaboration work on the phase-transition and electronic-structure evolution in W-doped \ce{MoTe2} is documented in Chapter 5. In this work, I contributed expertise in photoemission to study the critical dopant stoichiometry responsible for the phase transition.

Physics

Condensed matter

Graphite intercalation compounds

Surface chemistry

Electrons

The electrochemical synthesis and characterization of graphite intercalation compounds and luminescent porous silicon

Zhang, Zhengwei

17 August 1995

Graduation date: 1996

Porous silicon

Photoluminescence

Scanning tunneling microscopy

Estudo em nanocompósitos e eletrólitos poliméricos por ressonância magnética. / Study of nanocomposite and polymer eletrolyte by magnetic resonance

Antonio Carlos Bloise Junior

21 January 2003

Foram realizadas pesquisas em uma série de condutores iônicos que apresentam aplicações na área dos dispositivos eletroquímicos de estado sólido, utilizando-se basicamente a técnica de Ressonância Magnética Nuclear (RMN). A primeira parte deste trabalho é dedicada aos compostos de intercalação baseados na matriz de dissulfeto de molibdênio (MoS2) onde as espécies intercalantes (íons de lítio e moléculas de aminas) são inseridas num espaço de dimensionalidade reduzida gerado pela matriz. Já a segunda parte envolve os condutores iônicos poliméricos do tipo compósitos, nos quais foram utilizadas nanopartículas de carbono (Carbon Black) e titânio (TiO2) no eletrólito formado pelo poli(óxido de etileno) (POE) e o perclorato de lítio (LiClO4). Todos estes sistemas apresentam, em geral, uma considerável complexidade estrutural, o que significa que os movimentos moleculares e de difusão iônica se produzem num meio semicristalino (caso dos compósitos) ou num meio de dimensionalidade reduzida (caso dos intercalados). A espectroscopia de RMN dos núcleos de 7Li e 1H é uma técnica conveniente para o estudo destes materiais, pois é possível avaliar, através dos resultados obtidos das medidas dos tempos de relaxação e formas de linha, os efeitos provocados pela baixa dimensionalidade dos movimentos em estruturas laminares (caso dos intercalados), bem como identificar e aferir as interações e os mecanismos de relaxação resultantes dos diferentes graus de liberdade dos movimentos (iônicos e moleculares), fornecer parâmetros estruturais (distâncias interatômicas) que auxiliam na proposta de possíveis modelos estruturais e caracterizar completamente a escala temporal dos movimentos iônicos e moleculares. / Nuclear Magnetic Resonance (RMN) techniques were used to study a series of ionic conductor materials, which present applications in the area of the solid-state electrochemical devices. The first part of this work is dedicated to the study of intercalation compounds based on the molybdenum disulfide matrix (MoS2), where the intercalated species (lithium ion and amine molecule) are inserted in the low-dimensionality space generated by the matrix. The second part involves the study of a composite polymer electrolyte, employing fillers like Carbon Black and titanium dioxide (Tio2) nano particles in the electrolyte formed by the poly(ethy1ene oxide) and a lithium salt (LiClO4). In general, these systems present a considerable structural complexity, meaning that the molecular movements and ionic diffusion are produced in a semicrystalline environment (case of the composites) or in an environment of reduced dimensionality (case of intercalates). The 7Li and 1H NMR spectroscopy is a convenient technique for the study of these materials. Relaxation time and line shape measurements may provide a tool to investigate the effects provoked by the low-dimensionality of the movements in laminate structures (case of intercalate), to identify the interactions and relaxation mechanisms of the ionic and molecular motions, to supply structural parameters (interatomic distances) that would help the proposal of possible structural models, and finally, to characterize the time scale of the ionic and molecular movements completely.

Compóstios

Intercalados

RMN

Composite polymer electrolyte

Intercalation compounds

NMR

The Study Of Three Different Layered Structures As Model Systems For Hydrogen Storage Materials

Öztek, Muzaffer Tonguç

01 January 2011

The strength and success of the hydrogen economy relies heavily on the storage of hydrogen. Storage systems in which hydrogen is sequestered in a solid material have been shown to be advantageous over storage of hydrogen as a liquid or compressed gas. Many different types of materials have been investigated, yet the desired capacity and uptake/release characteristics required for implementation have not been reached. In this work, porphyrin aggregates were investigated as a new type of material for hydrogen storage. The building blocks of the aggregates are porphyrin molecules that are planar and can assume a face to face arrangement that is also known as H-aggregation. The H-aggregates were formed in solution, upon mixing of aqueous solutions of two different porphyrins, one carrying positively charged and the other one carrying negatively charged functional groups. The cationic porphyrin used was meso-tetra(4- N,N,N-trimethylanilinium) porphine (TAP) and it was combined with four different anionic porphyrins, meso-tetra(4-sulfonatophenyl)porphine (TPPS), meso-tetra(4-carboxyphenyl) porphine (TCPP), Cu(II) meso-tetra(4-carboxyphenyl) porphine, and Fe(III) meso-tetra(4- carboxyphenyl) porphine. The force of attraction that held two oppositely charged porphyrin molecules together was electrostatic attraction between the peripheral groups. Solid state aggregates were successfully isolated either by solvent evaporation or by centrifuging and freeze drying. TCPP-TAP and Cu(II)TCPP-TAP aggregates were shown to interact with hydrogen starting from 150 °C up to 250 °C. The uptake capacity was about 1 weight %. Although this value is very low, this is the first observation of porphyrin aggregates absorbing hydrogen. This opened the way for further research to improve hydrogen absorption properties of these iv materials, as well as other materials based on this model. Two other materials that are also based on planar building blocks were selected to serve as a comparison to the porphyrin aggregates. The first of those materials was metal intercalated graphite compounds. In such compounds, a metal atom is placed between the layers of graphene that make up the graphite. Lithium, calcium and lanthanum were selected in this study. Theoretical hydrogen capacity was calculated for each material based on the hydriding of the metal atoms only. The fraction of that theoretical hydrogen capacity actually displayed by each material increased from La to Ca to Li containing graphite. The weight % hydrogen observed for these materials varied between 0.60 and 2.0 %. The other material tested for comparison was KxMnO2, a layered structure of MnO2 that contained the K atoms in between oxygen layers. The hydrogen capacity of the KxMnO2 samples was similar to the other materials tested in the study, slightly above 1 weight %. This work has shown that porphyrin aggregates, carbon based and manganese dioxide based materials are excellent model materials for hydrogen storage. All three materials absorb hydrogen. Porphyrin aggregates have the potential to exhibit adjustable hydrogen uptake and release temperatures owing to their structure that could interact with an external electric or magnetic field. In the layered materials, it is possible to alter interlayer spacing and the particular intercalates to potentially produce a material with an exceptionally large hydrogen capacity. As a result, these materials can have significant impact on the use of hydrogen as an energy carrier.

Graphite intercalation compounds

Hydrogen as fuel

Layer structure (Solids)

Manganese

Porphyrins

Chemistry

Graphite Negative and Positive Electrodes for Alkali Metal-Ion and Dual-Carbon Batteries Using Ionic Liquid Electrolytes / イオン液体電解質を用いたアルカリ金属イオン電池およびデュアルカーボン電池のグラファイト負極および正極に関する研究

Yadav, Alisha

24 July 2023

京都大学 / 新制・課程博士 / 博士(エネルギー科学) / 甲第24853号 / エネ博第462号 / 新制||エネ||87(附属図書館) / 京都大学大学院エネルギー科学研究科エネルギー基礎科学専攻 / (主査)教授 野平, 俊之, 教授 萩原, 理加, 教授 佐川, 尚 / 学位規則第4条第1項該当 / Doctor of Energy Science / Kyoto University / DFAM

Graphite Intercalation Compounds

Ionic Liquid Electrolytes

Dual-Carbon Batteries

Potassium-Ion Batteries

Graphite Electrodes

501

Materiais à base de hidróxidos duplos lamelares de cobalto e alumínio: intercalação, reatividade e formação de compósitos por pirólise / Materials based on cobalt and aluminum layered double hydroxides: intercalation, reactivity and composites formation by pyrolysis

Macedo, Rafael dos Santos

17 March 2017

O presente trabalho trata da preparação e caracterização de três tipos de materiais, todos envolvendo hidróxidos duplos lamelares (HDLs) contendo íons cobalto e alumínio na composição das lamelas. Primeiramente, avaliou-se a influência de parâmetros de síntese na obtenção de HDLs intercalados com os ânions inorgânicos carbonato, cloreto e nitrato. Segundo dados de espectroscopia eletrônica UV-VIS, ressonância paramagnética eletrônica (EPR) e espectroscopia de fotoelétrons excitados por raios X (XPS), ocorre a oxidação parcial do Co2+ em Co3+ na lamela de HDL e, no caso do material contendo íon carbonato, observa-se a presença de radical carbonato, demonstrando a reatividade redox das matrizes com íons cobalto. A segunda parte do trabalho consistiu na intercalação do ânion derivado do ácido 2- aminotereftálico (ATA) em HDL. A presença do cátion cobalto nas lamelas e do grupo amino na espécie orgânica promoveu alterações significativas nas propriedades eletrônicas e térmicas do material (abreviado Co2Al-ATA). Assim como na primeira parte desta tese, as transformações ocorridas com o íon ATA devem incluir a formação inicial de um radical orgânico (de modo similar à polimerização da anilina), para o qual o agente oxidante é o íon Co3+ lamelar. Os dados de espectroscopia vibracional (no infravermelho e Raman) e de XPS mostram a presença de segmentos reduzidos (benzenóide) e oxidados (quinóides) na espécie intercalada. A solubilização do HDL em meio ácido permitiu isolar um material orgânico de cor preta que possui segmentos semiquinóides (radical orgânico) em sua estrutura, além dos reduzidos. A última etapa da presente tese consistiu em pirolisar o material Co2Al-ATA mencionado acima. Verificou-se que a alteração no procedimento de pirólise, como a temperatura, o desenho do forno, a forma do cadinho (cilíndrico ou barca), o tempo de resfriamento do sistema ou a atmosfera dinâmica ou estática, por exemplo, afetam as propriedades do produto final de decomposição. Nos compósitos obtidos, as fases inorgânicas provenientes da decomposição do HDL foram uma mistura de óxidos mistos de cobalto e alumínio (Co(CoxAl1-x)2O4), óxido de cobalto (CoO) e cobalto metálico. A fase de carbono apresentou perfil espectral de carbono grafítico nanocristalino e foi obtida em valores de temperatura de pirólise superiores a 800°C. Os compósitos contendo nanopartículas de cobalto metálico são ferromagnéticos. A reatividade redox dos HDLs de cobalto e as propriedades de seus produtos de decomposição apresentam potencial para aplicação em dispositivos eletroquímicos. / The present work reports the preparation and characterization of three types of materials, all involving layered double hydroxides (LDHs) containing cobalt and aluminum ions in the layer composition. First, the influence of synthetic parameters on the production of LDHs intercalated with the inorganic anions carbonate, chloride and nitrate was evaluated. According to UV-VIS electronic spectroscopy, electron paramagnetic resonance (EPR) and x-ray photoelectron spectroscopic (XPS) data, the partial oxidation of Co2+ to Co3+ occurs in the LDH layer and, in the case of the material containing carbonate ion, the presence of carbonate radical species demonstrates the redox reactivity of the matrices with cobalt ions. The second part of the work comprised the intercalation of the anion derived from 2- aminoterephthalic acid (ATA) in to LDH. The presence of the cobalt cation in the layer and the amino group in the organic species promoted significant changes in the electronic and thermal properties of the material (abbreviated Co2Al-ATA). As in the first part of this thesis, transformations occurring with the ATA ion should include the initial formation of an organic radical (similar to aniline polymerization), for which the oxidizing agent is the Co3+ ion in the layer. The vibrational (infrared and Raman) spectroscopy and XPS data show the presence of reduced (benzenoid) and oxidized (quinoids) segments in the intercalated species. The solubilization of HDL in acid medium allowed the isolation of a black organic material that has semiquinoid (organic radical) segments in its structure besides the reduced one. The last stage of the present thesis consisted of pyrolysis of the Co2Al-ATA material mentioned above. It was observed that the change in pyrolysis procedure, such as temperature, furnace design, crucible shape (bark or cylinder), system cooling time or dynamic or static atmosphere, for example, affects the properties of the final product of decomposition. In the obtained composites, the inorganic phases from the HDL decomposition were a mixture of mixed oxides of cobalt and aluminum (Co(CoxAl1-x)2O4), cobalt oxide (CoO) and metallic cobalt. The carbon phase showed nanocrystalline graphite carbon spectral profile and was obtained at pyrolysis temperature values above 800 °C. The composites containing metallic cobalt nanoparticles are ferromagnetic. The redox reactivity of HDLs containing cobalt and the properties of their decomposition products present potential for application in electrochemical devices

Cobalt

Cobalto

Compostos de intercalação

Hidróxidos duplos lamelares

Intercalation Compounds

Layered Double Hydroxides

Layered Materials

Materiais lamelares

Nanocarbonos

Nanocarbons

Materiais híbridos nanoestruturados à base de hidróxidos duplos lamelares e o fármaco sulindaco / Nanostructured hybrid materials based on layered double hydroxides and the sulindac drug

Rocha, Michele Aparecida

05 August 2015

Os hidróxidos duplos lamelares (HDLs) são matrizes inorgânicas bidimensionalmente estruturadas que apresentam propriedades diversas e interessantes para a formação de materiais híbridos. Em especial na área medicinal e farmacológica, o emprego de HDLs com lamelas contendo os íons Mg/Al e Zn/Al tem mostrado resultados promissores como antiácidos e como carregadores de fármacos. Por outro lado, anti-inflamatórios não esteroidais como o sulindaco são moléculas orgânicas ionizáveis que podem ser intercalados em HDLs levando à formação de materiais híbridos com potencial para uso na área farmacêutica. Este trabalho consistiu na síntese e na caracterização de materiais híbridos baseados em matrizes de HDLs de ZnRAl e MgRAl (R é a razão molar MII/Al) e o ânion derivado do fármaco sulindaco (abreviados M2IIAl-Sul). Foram avaliadas as condições experimentais mais apropriadas para a obtenção de materiais com alta cristalinidade e alto conteúdo do fármaco. Os materiais híbridos preparados por um método simples de coprecipitação (one pot) à temperatura ambiente e a 55°C apresentaram capacidade de carregamento de 50 a 55% (em massa) de sulindaco. Os difratogramas de raios X dos híbridos M2IIAl-Sul indicaram a formação de materiais mais cristalinos a 55°C, com várias reflexões basais indicando alto grau de organização das lamelas e distância interplanar de cerca de 2,74 nm. O arranjo bidimensional interdigitado dos ânions sulindaco entre as lamelas foi proposto através do mapa de densidade eletrônica unidimensional (1D Plot). A análise morfológica por microscopias eletrônicas de varredura e transmissão revelou a formação de estruturas nanométricas planas, flexíveis e desordenadas no caso do Mg2Al-Sul; as partículas de Zn2Al-Sul também apresentam nanoscrolls, com cerca de 100 nm de diâmetro, uma morfologia que não havia sido reportada até então para HDLs. Os espectros vibracionais no infravermelho dos materiais híbridos mostraram bandas típicas do sulindaco atribuídas ao vS=O em 1011 e 1039 cm-1, ao vC-F em 1163 cm-1 e bandas referentes aos estiramentos antissimétrico e simétrico do grupo COO- em aproximadamente 1564 e 1394 cm-1, que confirmam a presença do sulindaco na forma aniônica no sistema híbrido. Deslocamentos de picos observados nos espectros de ressonância magnética nuclear de carbono-13 no estado sólido sugerem que o confinamento entre as lamelas promove alterações na densidade de carga da espécie orgânica. As técnicas espectroscópicas confirmam a manutenção da integridade química do fármaco após o processo de intercalação. As atribuições dos espectros vibracionais e de ressonância magnética nuclear foram efetuadas com o auxílio do método da Teoria do Funcional de Densidade (DFT) para a espécie orgânica. A avaliação do comportamento térmico por termogravimetria acoplada à calorimetria exploratória diferencial e à espectrometria de massas (TG-DTA-MS) evidencia sensível aumento na estabilidade térmica do fármaco intercalado em matriz de Zn2Al. Esse fato foi interpretado através da análise dos espectros vibracionais de amostras aquecidas a 250°C. Propõe-se que a desidroxilação das lamelas do HDL de zinco promove a coordenação do grupo carboxilato do ânion sulindaco ao metal divalente, aumentando sua estabilidade térmica. Os ensaios de dissolução in vitro evidenciam um mecanismo difusional de liberação modificada (prolongada) do fármaco a partir do material híbrido, que ocorre em cerca do dobro do tempo observado para o sulindaco não intercalado. Resultados preliminares de estudo in vivo de pastilhas dos materiais híbridos implantadas em região intramuscular de ratos atestam a biocompatibilidade e a antigenicidade dos materiais HDL-Cl e dos híbridos HDL-Sul. / Layered double hydroxides (LDHs) are two-dimensionally structured inorganic matrices that show diverse and interesting properties for hybrid materials development. Particularly in the medical and pharmaceutical area, the use of LDHs with layers containing Zn/Al and Mg/Al ions has shown promising results. On the other hand, nonsteroidal drugs such as sulindac are ionizable organic molecules that can be intercalated into LDH leading to the formation of hybrid materials with potential usage in the pharmaceutical area. This work involved the synthesis and characterization of hybrid materials based on matrices of LDHs ZnRAl and MgRAl (R is the MII/Al molar ratio) and the anion derived from the sulindac drug (abbreviated M2IIAl-Sul). The most suitable experimental conditions for obtaining materials with high crystallinity and also high drug contents were evaluated. Hybrid materials prepared by a simple coprecipitation method (one pot) at room temperature and 55 °C showed loading capacity of about 50 - 55% (by mass) of sulindac. X-ray diffraction revealed the formation of higher crystalline materials at 55 °C; various basal reflections indicate a high degree of layers stacking and an interlayer distance of about 2.74 nm to M2IIAl-Sul hybrids. A two-dimensional array of interdigitated sulindac anions between the layers was proposed by one-dimensional electron density map (1D Plot). The morphological analysis by electronic scanning and transmission microscopies revealed the formation of flat, flexible and disordered nanoscale structures in the case of Mg2Al-Sul; nanoscrolled particles of about 100 nm in diameter are also present in Zn2Al-Sul sample, a morphology which had not been reported so far for LDHs. The vibrational spectra of hybrid materials in the infrared showed the characteristic sulindac bands assigned to vS=O at 1011 and 1039 cm-1, the vCF at 1163 cm-1 and bands related to the antisymmetric and symmetric stretching of the -COO- group at approximately 1564 and 1394 cm-1 which confirmed the presence of the anion sulindac in the hybrid system. Shift peaks observed in carbon-13 nuclear magnetic resonance spectra in solid state suggest that the confinement between the layers promotes variations in the organic species charge density. Spectroscopic techniques confirm the maintenance of the chemical integrity of the drug after the intercalation process. The spectral assignments of the organic species were supported by Density Functional Theory (DFT). The evaluation of the thermal behavior by thermogravimetry coupled with differential scanning calorimetry and mass spectrometry (TG-DSC-MS) shows substantial increase in the thermal stability of the drug intercalated into Zn2Al matrix. This effect was interpreted by analysis of vibrational spectra of samples calcined at 250 °C. It is proposed that dehydroxylation of the Zn2Al layers promotes the coordination of the sulindac carboxylate group to the divalent metal. In vitro dissolution tests of hybrid material show a diffusional mechanism of modified drug release (sustained), which occurs in about twice the time observed for sulindac not intercalated. Preliminary results from in vivo study of hybrid materials\' pellets implanted in the intramuscular region of rats attest to biocompatibility and antigenicity of LDH-Cl and LDH-Sul hybrid materials

Compostos de intercalação

Drug

Drug delivery

Fármacos

Hidróxidos duplos lamelares

Intercalation compounds

Layered double hydroxides

Liberação modificada de fármacos

Sulindac

Sulindaco