Preparation, characterization and catalytic studies of V2O5-SiO2 xerogel composite

In this work, we report the synthesis, characterization and catalytic properties of a vanadium oxide-silicon oxide composite xerogel prepared by a soft chemistry approach. In order to obtain such material, we submitted a vanadium pentoxide gel previously synthesized via protonation of metavanadate species to an ""in situ"" progressive polycondensation into silica gel. The material has been characterized by X-ray diffraction, infrared spectroscopy, thermogravimetric analysis and scanning electron microscopy. Further, the catalytic activity of this material was evaluated for the epoxidation of styrene and cyclooctene using iodosylbenzene, hydrogen peroxide and m-chloroperbenzoic acid as the oxidizing agent.

Synthesis, characterization, and catalytic properties of a mesostructured lamellar xerogel tungsten oxide phase

Cetyltrimethylammonium bromide (CTAB) and n-hexadecylamine (HDA) have been used as template in the synthesis of a mesolamellar xerogel tungsten oxide phase (WO(3)/CTAB/HDA). The catalytic properties of the resulting material were investigated in the oxidation of cis-cyclooctene, styrene, and cyclohexane, using hydrogen peroxide (H(2)O(2)), terc-butyl hydroperoxide (t-BOOH), or m-chlorperbenzoic acid (m-CPBA) as oxygen transfer agent. In general, the catalytic results were comparable to those obtained with related systems, thus suggesting the potential application of this material as catalyst for epoxidation reactions. (C) 2011 Elsevier B.V. All rights reserved.

Xerogel p-anisidinapropilsílica: estudo da estabilidade térmica e da resistência à lixiviação com solventes

The xerogel p-anisidinepropylsilica was obtained. This solid presents some residual paraffin and also a small fraction of high organofunctionalized material that was leached in polar solvent. The xerogel purification could be achieved by exhaustively washing with hexane and dichloromethane solvents, or submitting the xerogel to thermal treatment up to 300 ºC, in vacuum. The resulting purified xerogel material present an appreciable thermal stability and resistance to leaching by solvents.

Extração de Al(III), Cr(III) e Fe(III) de meio etanólico usando o xerogel anilinapropilsílica

In this study, the preparation of the xerogel anilinepropylsilica is reported. The ability of the xerogel for extracting Al(III), Cr(III) and Fe(III) from ethanol was investigated at 25 ºC. The xerogel adsorption capacities were obtained from the adsorption isotherms by using the batch method. Flame atomic absorption spectrometry (FAAS) was used to estimate the concentration of metal ions in solution. The adsorption affinity follows the series Cr(III) > Fe(III) > Al(III) and the maximum adsorption capacities of the metal ions were 0.61, 0.52 and 0.43 mmol g-1, respectively.

Thermal annealing effects on vanadium pentoxide xerogel films

The effect of water molecules on the conductivity and electrochemical properties of vanadium pentoxide xerogel was studied in connection with changes of morphology upon thermal annealing at different temperatures. It was demonstrated that the conductivity was increased for the samples heated at 150ºC and 270ºC compared to the vanadium pentoxide xerogel. It was also verified a stabilization of electrochemical processes of the insertion and de-insertion of lithium ions the structure of thermally annealed vanadium pentoxide.

Influence of the synthesis conditions on the characteristics and metal adsorption properties of the 3-(1,4-phenylenediamine)propylsilica xerogel

The hybrid 3-(1,4-phenylenediamine)propylsilica xerogel was obtained starting from two different organic precursor quantity (5 and 8 mmol) to 22 mmol of TEOS, in the synthesis. The xerogel samples were characterized by using CHN elemental analysis, N2 adsorption-desorption isotherms, infrared thermal analysis. The xerogel was used as metal sorbent for Cu2+, Cd2+ and Pb2+ in aqueous solution with concentration range of 10-3 to 10-5 mmol l-1. The quantity of organic precursor added in the synthesis influences the characteristics of the xerogel as morphology and thermal stability, as well as the metal adsorption capacity.

Atrazine persistence applied as commercial and xerogel formulations in oxisol

The intensive use of pesticides have contaminated the soil and groundwater. The application of herbicides as controlled release formulations may reduce the environmental damage related to their use because it may optimize the efficiency of the active ingredient and reducing thus the recommended dose. The objective of this study was to evaluate the persistence of the herbicide atrazine applied as commercial formulation (COM) and as controlled release formulation (xerogel - XER) in Oxisol. The experimental design used was split-plot randomized-blocks with four replications, in a (2 x 6) + 1 arrangement. The two formulations (COM and XER) were assigned to main plots and different atrazine concentrations (0, 3.200, 3.600, 4.200, 5.400 and 8.000 g atrazine ha-1) were assigned to sub-plots. Persistence was determined by means of dissipation kinetics and bioavailability tests. The methodology of bioassays to assess the atrazine availability is efficient and enables to distinguish the tested formulations. The availability of atrazine XER is higher than the commercial in two different periods: up to 5 days after herbicide application and at the 35th day after application. The XER formulation tends to be more persistent in relation to COM formulation.

Leaching of Atrazine in Commercial and Xerogel Formulations in Oxisol Using Bioassay and Chromatographic Methods

Mobility of atrazine in soil has contributed to the detection of levels above the legal limit in surface water and groundwater in Europe and the United States. The use of new formulations can reduce or minimize the impacts caused by the intensive use of this herbicide in Brazil, mainly in regions with higher agricultural intensification. The objective of this study was to compare the leaching of a commercial formulation of atrazine (WG) with a controlled release formulation (xerogel) using bioassay and chromatographic methods of analysis. The experiment was a split plot randomized block design with four replications, in a (2 x 6) + 1 arrangement. The main formulations of atrazine (WG and xerogel) were allocated in the plots, and the herbicide concentrations (0, 3200, 3600, 4200, 5400 and 8000 g ha-1), in the subplots. Leaching was determined comparatively by using bioassays with oat and chromatographic analysis. The results showed a greater concentration of the herbicide in the topsoil (0-4 cm) in the treatment with the xerogel formulation in comparison with the commercial formulation, which contradicts the results obtained with bioassays, probably because the amount of herbicide available for uptake by plants in the xerogel formulation is less than that available in the WG formulation.

Singlet Oxygen in Microporous Silica Xerogel:Quantum Yield and Oxidation at the Gas–Solid Interface

The quantum yields of singlet oxygen production and lifetimes at the gas–solid interface in silica gel material are determined. Different photosensitizers (PS) are encapsulated in parallelepipedic xerogel monoliths (PS-SG). PS were chosen according to their known photooxidation properties: 9,10-dicyanoanthracene (DCA), 9,10-anthraquinone (ANT), and a benzophenone derivative, 4-benzoyl benzoic acid (4BB). These experiments are mainly based on time-resolved 1O2 phosphorescence detection, and the obtained FD and tD values are compared with those of a reference sensitizer for production, 1H-phenalen-1- one (PN), included in the same xerogel. The trend between their ability to oxidize organic pollutants in the gas phase and their efficiency for production is investigated through photooxidation experiments of a test pollutant dimethylsulfide (DMS). The FD value is high for DCA-SG relative to the PN reference, whereas it is slightly lower for 4BB-SG and for ANT-SG. FD is related to the production of sulfoxide and sulfone as the main oxidation products for DMS photosensitized oxidation. Additional mechanisms, leading to C!S bond cleaveage, appear to mainly occur for the less efficient singlet oxygen sensitizers 4BB-SG and ANTSG.

Síntese, caracterização e estudo das propriedades adsorventes do xerogel p-anisidinapropilsilica

Neste trabalho foram estudadas a síntese, a caracterização, a estabilidade térmica e as propriedades adsorventes de um novo xerogel híbrido, p-anisidinapropilsílica. O material foi sintetizado a partir do método sol-gel utilizando como precursor orgânico a p-anisidinapropiltrimetoxisilano (AnPTMS), também sintetizado em nosso laboratório. O precursor orgânico foi gelatinizado simultaneamente com tetraetilortosilicato (TEOS). Foram sintetizadas cinco amostras de xerogéis contendo diferentes graus de incorporação orgânica. A incorporação orgânica foi monitorada a partir da variação da concentração de precursor orgânico adicionado, nos valores: 0,05; 0,15; 0,23; 0,35; e 0,46 mol.l-1, sendo que os xerogéis resultantes foram designados como A, B, C, D e E, respectivamente. Os xerogéis foram tratados termicamente sob vácuo e analisados por espectroscopia no infravermelho (Termoanálise na região do Infravermelho). Os espectros mostraram que a área sob a banda em 1500 cm-1, devida ao anel aromático da p-anisidina, diminui com o aumento da temperatura do tratamento térmico e esta diminuição é mais pronunciada nos materiais cuja incorporação orgânica foi menor. Entretanto, os xerogéis com maior incorporação orgânica (amostras D e E) apresentaram boa estabilidade térmica da fase orgânica até a temperatura de 300 oC Foram obtidas isotermas de adsorção e dessorção de nitrogênio para as amostras A, B, C e D, sendo que a partir delas foram obtidas a área superficial, volume e distribuição do tamanho de poros dos xerogéis. Todas as amostras mostraram porosidade na região de mesoporos (2-50 nm), entretanto, foi observado que o aumento da incorporação orgânica resultou em diminuição da área superficial bem como do tamanho dos mesoporos dos xerogéis. Entretanto, todas as amostras mostraram boa estabilidade térmica morfológica, visto que não foram observadas variações significativas na distribuição de poros com aquecimento até a temperatura de 350 oC. Os xerogéis foram lavados com hexano e diclorometano para a remoção de parafina e pequenas frações de oligômero altamente organofuncionalizado residuais. A amostra D foi utilizada como fase estacionária em coluna de pré-concentração de uma amostra padrão de ésteres ftálicos, mostrando um promissor desempenho.

Monitoramento morfológico do xerogel híbrido 3-(1,4-fenilenodiamina)propil/silica obtido sob diferentes condições de síntese

Neste trabalho, foi obtido o xerogel híbrido 3-(1,4-fenilenodiamina) propil/sílica, usando-se o método sol-gel de síntese, variando-se as condições experimentais de síntese. Foram usados como reagentes precursores o tetraetilortosilicato (TEOS) e o 3-[(1,4-fenilenodiamina)propil]trimetoxisilano (FDAPS) sintetizado em nosso laboratório. As condições experimentais de síntese variadas foram: a concentração de precursor orgânico (FDAPS), a temperatura de gelificação, o tipo de solvente e o pH do meio reacional. O trabalho foi dividido em duas etapas: na primeira, foram obtidas duas séries de materiais onde se variou a temperatura de gelificação (5, 25, 50 e 70 °C), além da quantidade de precursor orgânico (FDAPS), adicionado à síntese (1,5 e 5,0 mmol). Na segunda etapa variou-se o pH do meio reacional (4, 7 e 10) além do tipo de solvente (etanol, butanol e octanol), mantendo-se a quantidade de precursor orgânico adicionado e a temperatura de gelificação constantes em 5,0 mmol e 25 oC, respectivamente. Em ambas etapas utilizou-se HF como catalisador e manteve-se o sistema fechado, porém não vedado, durante a gelificação. Na caracterização dos xerogéis híbridos foram usadas as seguintes técnicas: a) termoanálise no infravermelho, para estimar a estabilidade térmica do componente orgânico além da fração de orgânicos dispersos na superfície; b) isotermas de adsorção e dessorção de nitrogênio, para determinação da área superficial específica, do volume e da distribuição de tamanho de poros; c) análise elementar para estimar a fração de componente orgânico presente no xerogel e d) microscopia eletrônica de varredura onde foi possível observar textura, compactação e presença de partículas primárias nos xerogéis. A partir dos resultados de caracterização foi possível avaliar a influência dos parâmetros experimentais de síntese nas características dos xerogéis híbridos obtidos. Xerogéis híbridos com maior teor de orgânicos foram mais influenciados pela variação da temperatura de gelificação. Um aumento na temperatura de gelificação produz xerogéis com menor porosidade, entretanto, com maior estabilidade térmica do componente orgânico. Considerando-se estabilidade térmica e porosidade, as amostras gelificadas a 25 oC apresentaram os melhores resultados. Em relação à variação de pH e solvente, as amostras gelificadas em pH ácido foram as que apresentaram maior porosidade, enquanto que a maior estabilidade térmica foi alcançada usando-se etanol como solvente.

Aplicação da 4-fenilenodiaminopropilsílica xerogel como adsorvente na pré-concentração de cobre em águas

Neste trabalho utilizou-se um adsorvente híbrido mesoporoso, a 4- fenilenodiaminopropilsílica (4-PhAP/sílica) que foi obtida através do processo sol-gel. O material foi caracterizado através de espectroscopia de infravermelho, análise elementar de carbono, hidrogênio e nitrogênio (CHN). Na continuidade do trabalho o adsorvente foi empregado na pré-concentração de amostras certificadas de água com posterior determinação de Cu2+ por espectroscopia de absorção atômica com forno de grafite (GFAAS). A massa característica de Cu2+ encontrada foi 15,0 ± 0,2 pg, sendo que o limite de detecção na determinação de cobre em água empregando o procedimento de préconcentração foi 0,2 µg l-1. Foi possível realizar em torno de 750 ciclos de leitura com o mesmo tubo de grafite. Durante a pré-concentração, agitou-se dentro em um frasco de polietileno: aliquotas de 5,00 ml de água certificadas, 20,0 ml de tampão acetato (pH 5,2) e 20,0 mg do adsorvente. Após 60 minutos de contato, separou-se a fase sólida contendo adsorvente mais adsorbato da fase líquida através de filtração, suspendeu-se então 15,0 mg do adsorvente contendo Cu2+ em 1 ml de solução contendo HNO3 0,5% e Triton X-100 0.05%. No prosseguimento do trabalho 20,0 µl desta suspensão foi diretamente introduzida numa plataforma integrada de um tubo de grafite, previamente tratada com modificador permanente W-Rh. O fator de pré-concentração obtido com a utilização do xerogel 4-PhAP/sílica como adsorvente foi 3,75, sendo que a capacidade de retenção do adsorvente foi 0,52 mmol de cobre por grama de material adsorvente.

Immobilization of marine fungi on silica gel, silica xerogel and chitosan for biocatalytic reduction of ketones

The scanning electron microscopy (SEM) analysis showed that whole living hyphal of marine fungi Aspergillus sclerotiorum CBMAI 849 and Penicillium citrinum CBMAI 1186 were immobilized on support matrices of silica gel, silica xerogel and/or chitosan. P. citrinum immobilized on chitosan catalyzed the quantitative reduction of 1-(4-methoxyphenyl)-ethanone (1) to the enantiomer (S)-1-(4-methoxyphenyl)-ethanol (3b), with excellent enantioselectivity (ee > 99%, yield = 95%). Interestingly, ketone 1 was reduced with moderate selectivity and conversion to alcohol 3b (ee = 69%, c 40%) by the free mycelium of P. citrinum. This free mycelium of P. citrinum catalyzed the production of the (R)-alcohol 3a, the antipode of the alcohol produced by the immobilized cells. P. citrinum immobilized on chitosan also catalyzed the bioreduction of 2-chloro-1-phenylethanone (2) to 2-chloro-1-phenylethanol (4a,b), but in this case without optical selectivity. These results showed that biocatalytic reduction of ketones by immobilization hyphal of marine fungi depends on the xenobiotic substrate and the support matrix used. (c) 2012 Elsevier B.V. All rights reserved.

Investigation of the electrical and electrochemical properties of nanocomposites from V2O5, polypyrrole, and polyaniline

In this work, an investigation of the electrical and electrochemical properties responsible for the energy storage capability of nanocomposites has been carried out. We demonstrate that, in the case of the V2O5 xerogel and the nanocomposites polypyrrole (Ppy)/V2O5 and polyaniline (PANI)/V2O5, the quadratic logistic equation (QLE) can be used to fit the inverse of the resistance values as a function of the injected charge in non-steady-state conditions. This contributes to a phenomenological understanding of the lithium ion and electron transport. The departure of the experimental curve from the fitting observed for the V2O5 xerogel can be attributed to the trapping sites formed during the lithium electroinsertion, which was observed by electrochemical impedance spectroscopy. The amount of trapping sites was obtained on the basis of the QLE. Similar values used to fit the inverse of the resistance were also used to fit the absorbance changes, which is also associated with the small polaron hopping from the V(IV) to the V(V) sites. On the other hand, there was good agreement between the experimental and the theoretical data when the profile of the inverse of the resistance as a function of the amount of inserted lithium ions of the nanocomposites Ppy/V2O5 and PANI/ V2O5 was concerned. We suggest that the presence of the conducting polymers is responsible for the different electrical profile of the V2O5 xerogel compared with those of the nanocomposites. In the latter case, interactions between the lithium ions and oxygen atoms from V2O5 are shielded, thus decreasing the trapping effect of lithium ions in the V2O5 sites. The different values of the lithium ion diffusion coefficient into these intercalation materials are in agreement with this hypothesis.