Surface structure effects on the electrochemical oxidation of ethanol on platinum single crystal electrodes

Ethanol oxidation has been studied on Pt(111), Pt(100) and Pt(110) electrodes in order to investigate the effect of the surface structure and adsorbing anions using electrochemical and FTIR techniques. The results indicate that the surface structure and anion adsorption affect significantly the reactivity of the electrode. Thus, the main product of the oxidation of ethanol on the Pt(111) electrode is acetic acid, and acetaldehyde is formed as secondary product. Moreover, the amount of CO formed is very small, and probably associated with the defects present on the electrode surface. For that reason, the amount of CO(2) is also small. This electrode has the highest catalytic activity for the formation of acetic acid in perchloric acid. However, the formation of acetic acid is inhibited by the presence of specifically adsorbed anions, such as (bi) sulfate or acetate, which is the result of the formation of acetic acid. On the other hand, CO is readily formed at low potentials on the Pt(100) electrode, blocking completely the surface. Between 0.65 and 0.80 V, the CO layer is oxidized and the production of acetaldehyde and acetic acid is detected. The Pt(110) electrode displays the highest catalytic activity for the splitting of the C-C bond. Reactions giving rise to CO formation, from either ethanol or acetaldehyde, occur at high rate at any potential. On the other hand, the oxidation of acetaldehyde to acetic acid has probably the lower reaction rate of the three basal planes.

Complex kinetics, high frequency oscillations and temperature compensation in the electro-oxidation of ethylene glycol on platinum

Despite the fact that the majority of the catalytic electro-oxidation of small organic molecules presents oscillatory kinetics under certain conditions, there are few systematic studies concerning the influence of experimental parameters on the oscillatory dynamics. Of the studies available, most are devoted to C1 molecules and just some scattered data are available for C2 molecules. We present in this work a comprehensive study of the electro-oxidation of ethylene glycol on polycrystalline platinum surfaces and in alkaline media. The system was studied by means of electrochemical impedance spectroscopy, cyclic voltammetry, and chronoamperometry, and the impact of parameters such as applied current, ethylene glycol concentration, and temperature were investigated. As in the case of other parent systems, the instabilities in this system were associated with a hidden negative differential resistance, as identified by impedance data. Very rich and robust dynamics were observed, including the presence of harmonic and mixed mode oscillations and chaotic states, in some parameter region. Oscillation frequencies of about 16 Hz characterized the fastest oscillations ever reported for the electro-oxidation of small organic molecules. Those high frequencies were strongly influenced by the electrolyte pH and far less affected by the EG concentration. The system was regularly dependent on temperature under voltammetric conditions but rather independent within the oscillatory regime.

Eu3+ luminescence in tellurite glasses with gold nanostructures

Luminescence properties of Eu3+ doped TeO2-PbO-GeO2 glasses containing gold nanoparticles (NPs) were investigated. The emission spectra of the samples exhibited enhancement of Eu3+ luminescence due to the presence of gold NPs. The emission at 614 nm. due to the Eu3+ hypersensitive transition D-5(0)-F-7(2), is much influenced by the gold NPs and increases by approximate to 100%. for samples heat-treated at 350 degrees C during 41 h. (c) 2007 Elsevier B.V. All rights reserved.

Mechanisms of substitution reactions on cyclometallated platinum(IV) complexes: "Quasi-labile" systems

The substitution reactions of SMe2 by phosphines (PMePh2, PEtPh2, PPh3, P(4-MeC6H4)(3), P(3-MeC6H4)(3), PCy3) on Pt-IV complexes having a cyclometalated imine ligand, two methyl groups in a cis-geometrical arrangement, a halogen, and a dimethyl sulfide as ligands, [Pt(CN)(CH3)(2)(X)(SMe2)], have been studied as a function of temperature, solvent, and electronic and steric characteristics of the phosphines and the X and CN ligands. In all cases, a limiting dissociative mechanism has been found, where the dissociation of the SMe2 ligand corresponds to the rate-determining step. The pentacoordinated species formed behaves as a true pentacoordinated Pt-IV compound in a steady-state concentration, given the solvent independence of the rate constant. The X-ray crystal structures of two of the dimethyl sulfide complexes and a derivative of the pentacoordinate intermediate have been determined. Differences in the individual rate constants for the entrance of the phosphine ligand can only be estimated as reactivity ratios. In all cases an effect of the phosphine size is detected, indicating that an associative step takes place from the pentacoordinated intermediate. The nature of the (CN) imine and X ligands produces differences in the dimethyl sulfide dissociation reactions rates, which can be quantified by the corresponding DeltaS double dagger values (72, 64, 48, 31, and 78 J K-1 mol(-1) for CN/X being C6H4CHNCH2C6H5/Br, C6H4CHNCH2-(2,4,6-(CH3)(3))C6H2/Br, C6H4CHNCH2C6H5/Cl, C6Cl4CHNCH2C6H5/Cl, and C6W4CH2NCHC6H5/ Pr, respectively). As a whole, the donor character of the coordinated C-aromatic and X atoms have the greatest influence on the dissociativeness of the rate-determining step.

Activity of platinum-tin catalysts prepared by the Pechini-Adams method for the electrooxidation of ethanol

Pt-Sn electrocatalysts of different compositions were prepared and dispersed on carbon Vulcan XC-72 using the Pechini-Adams method. The catalysts were characterized by energy dispersive X-ray analysis and X-ray diffraction. The electrochemical properties of these electrode materials were also examined by cyclic voltammetry and chronoamperometric experiments in acid medium. The results showed that the presence of Sn greatly enhances the activity of Pt towards the electrooxidation of ethanol. Moreover, it contributes to reduce the amount of noble metal in the anode of direct alcohol fuel cells, which remains one of the challenges to make the technology of direct alcohol fuel cells possible. Electrolysis of ethanol solutions at 0.55 V vs. RHE allowed to determine by liquid chromatography acetaldehyde and acetic acid as the main reaction products. CO(2) was also analyzed after trapping it in a NaOH solution indicating that the cleavage of the C-C bond in the ethanol molecule did occur during the adsorption process. In situ IR reflectance spectroscopy helped to investigate in more details the reaction mechanism through the identification of the reaction products as well as the presence of some intermediate adsorbed species, such as linearly bonded carbon monoxide. (C) 2009 Elsevier B.V. All rights reserved.

Platinum nanoparticles embledded in layer-by-layer films from SnO2/polyallylamine for ethanol electrooxidation

Self-assembled films from SnO2 and polyallylamine (PAH) were deposited on gold via ionic attraction by the layer-by-layer(LbL) method. The modified electrodes were immersed into a H2PtCl6 solution, a current of 100 mu A was applied, and different electrodeposition times were used. The SnO2/PAH layers served as templates to yield metallic platinum with different particle sizes. The scanning tunnel microscopy images show that the particle size increases as a function of electrodeposition time. The potentiodynamic profile of the electrodes changes as a function of the electrodeposition time in 0.5 mol L-1 H2SO4, at a sweeping rate of 50mVs(-1). Oxygen-like species are formed at less positive potentials for the Pt-SnO2/PAH film in the case of the smallest platinum particles. Electrochemical impedance spectroscopy measurements in acid medium at 0.7 V show that the charge transfer resistance normalized by the exposed platinum area is 750 times greater for platinum electrode (300 k Omega cm(2)) compared with the Pt-SnO2/PAH film with 1 min of electrodeposition (0.4 k Omega cm(2)). According to the Langmuir-Hinshelwood bifunctional mechanism, the high degree of coverage with oxygen-like species on the platinum nanoparticles is responsible for the electrocatalytic activity of the Pt-SnO2/PAH concerning ethanol electrooxidation. With these features, this Pt-SnO2/PAH film may be grown on a proton exchange membrane (PEM) in direct ethanol fuel cells (DEFC). (c) 2008 Elsevier B.V. All rights reserved.

Study of Pt/MCM-22 based catalysts in the transformation of n-hexane: effect of rare earth elements and mode of platinum introduction

The bifunctional transformation of n-hexane was carried out over Pt/MCM-22 based catalysts. MCM-22 was synthesized and submitted to ion exchange with rare earth nitrate solutions of La, Nd and Yb, followed by Pt introduction. Three different methods were used to introduce about 1 wt% of Pt in the zeolite: ion exchange, incipient wetness impregnation and mechanical mixture with Pt/Al(2)O(3). The bifunctional catalysts were characterized by transmission electron microscopy and by the model reaction of toluene hydrogenation. These experiments showed that, in the ion exchanged sample, Pt is located both within the inner micropores and on the outer surface, whereas in the impregnated one, the metal is essentially located on the outer surface under the form of large particles. The presence of RE elements increases the hydrogenating activity of Pt/MCM-22 since the location of these species at the vicinity of metal particles causes modification on its electronic properties. Whatever the mode of Pt introduction, a fast initial decrease in conversion is observed for n-hexane transformation, followed by a plateau related to the occurrence of the catalytic transformations at the hemicages located at the outer surface of the crystals. The effect of rare earth elements on the hydrogenating function leads to a lower selectivity in dibranched isomers and increased amounts of light products.

Synthesis of titanate nanostructures using amorphous precursor material and their adsorption/photocatalytic properties

This article reports on a new and swift hydrothermal chemical route to prepare titanate nanostructures (TNS) avoiding the use of crystalline TiO2 as starting material. The synthesis approach uses a commercial solution of TiCl3 as titanium source to prepare an amorphous precursor, circumventing the use of hazardous chemical compounds. The influence of the reaction temperature and dwell autoclave time on the structure and morphology of the synthesised materials was studied. Homogeneous titanate nanotubes with a high length/diameter aspect ratio were synthesised at 160 degrees C and 24 h. A band gap of 3.06 +/- 0.03 eV was determined for the TNS samples prepared in these experimental conditions. This value is red shifted by 0.14 eV compared to the band gap value usually reported for the TiO2 anatase. Moreover, such samples show better adsorption capacity and photocatalytic performance on the dye rhodamine 6G (R6G) photodegradation process than TiO2 nanoparticles. A 98% reduction of the R6G concentration was achieved after 45 min of irradiation of a 10 ppm dye aqueous solution and 1 g L-1 of TNS catalyst.

Effect of annealing temperature on photoluminescence and resistive switching characteristics of ZnO/Al2O3 multilayer nanostructures

This work demonstrates the role of defects generated during rapid thermal annealing of pulsed laser deposited ZnO/Al2O3 multilayer nanostructures in presence of vacuum at different temperatures (Ta) (500–900 C) on their electrical conductance and optical characteristics. Photoluminescence (PL) emissions show the stronger green emission at Ta 600 C and violet–blue emission at TaP800 C, and are attributed to oxygen vacancies and zinc related defects (zinc vacancies and interstitials) respectively. Current–voltage (I–V) characteristics of nanostructures with rich oxygen vacancies and zinc related defects display the electroforming free resistive switching (RS) characteristics. Nanostructures with rich oxygen vacancies exhibit conventional and stable RS behavior with high and low resistance states (HRS/LRS) ratio 104 during the retention test. Besides, the dominant conduction mechanism of HRS and LRS is explained by trap-controlled-space-charge limited conduction mechanism, where the oxygen vacancies act as traps. On the other hand, nanostructures with rich zinc related defects show a diode-like RS behavior. The rectifying ratio is found to be sensitive on the zinc interstitials concentration. It is assumed that the rectifying behavior is due to the electrically formed interface layer ZnAl2O4 at the Zn defects rich ZnO crystals – Al2O3 x interface and the switching behavior is attributed to the electron trapping/de-trapping process at zinc vacancies.

Graphene-based nanostructures: Plasmonics in the THz range

The properties of surface plasmon-polaritons (SPPs) in graphene are discussed and several possible ways of coupling electromagnetic radiation in the terahertz (THz) spectral range to this type of surface waves are described: (i) the attenuated total reflection (ATR) method employing a prism, (ii) graphene-based gratings or graphene monolayers with modulated conductivity, (iii) a metal stripe on top of the graphene layer, and (iv) a nanoparticle located above it. Potentially interesting for applications SPP effects, such as switching, modulation and polarization of THz radiation, as well as its enhanced absorption in graphene, are considered. The discussion also concerns the impact of the nonlinear properties of graphene, such as optical bistability.

In vitro digestion and stability assessment of b-lactoglobulin/riboflavin nanostructures

B-Lactoglobulin (b-Lg) is the major protein fraction of bovine whey serum and a primary gelling agent. b-Lg has a high nutritional value, is stable at low pH being highly resistant to proteolytic degradation in the stomach, besides, it has the ability of acting as an encapsulating agent. This study aims at assessing the ability of b-Lg nanostructures to associate a nutraceutical - i.e. riboflavin - and release it in a controlled manner throughout an in vitro gastrointestinal (GI) system. For this reason b-Lg nanostructures loaded with riboflavin were critically characterized in terms of their morphology (i.e. size, polydispersity, -potential and shape) by dynamic light scattering (DLS) and transmission electron microscopy (TEM), and efficiency to associate to riboflavin through spectrofluorimetry. Furthermore, these nanocomplexes were evaluated in an in vitro GI model, simulating the physiological conditions. Stable b-Lg nanostructures were obtained at pH 6, of spherical shape, characterized by particle size of 172±1 nm, low polydispersity (i.e. PDI of 0.06±0.02), -potential of -32±3 mV and association efficiency (AE) of 26±1 %. b-Lg nanostructures showed to be stable upon their passage throughout stomach (i.e. particle size, PDI and potential of 248±10 nm, 0.18±0.03 and 18±3 mV, respectively). Concerning their passage throughout the intestine, such nanostructures were mostly degraded in the duodenum. Regarding riboflavin, a release of about 11 % was observed after their passage through stomach, while 35 %, 38 % and 5 % were the released percentages of the total riboflavin associated observed after passage through duodenum, jejunum and ileum, respectively. Hence,b-Lg nanostructures showed to be suitable carriers for riboflavin until the intestine, where their degradation occurs. b-Lg also showed to be structurally stable, under food simulant conditions (yoghurt simulant, composed of 3 % acetic acid), over 14 days, with a protective effect upon riboflavin activity, releasing it in a 7 day period.

Síntesis, caracterización y aplicaciones específicas de metalosilicatos cristalinos micro y mesoporosos con incorporación de nanoestructuras. Synthesis, characterization and specific aplications of crystalline micro and mesoporous metallosilicates with nanostructures.

La síntesis de materiales cristalinos micro y mesoporosos con incorporación de micro/nano partículas/clusters de especies formadas con entidades propias interaccionando con las redes, como óxidos de metales, cationes de neutralización, especies metálicas, etc., pueden potencialmente ser utilizados como "materiales hospedaje" en óptica, electrónica, sensores, como materiales magnéticos, en estrategias ambientales de control de la contaminación, catálisis en general y procesos de separación. Se sintetizaran y caracterizaran por diversas técnicas fisicoquímicas, zeolitas microporosas de poro medio (ZSM) y poro grande (Y), y materiales mesoporosos (MCM-41). La aplicación de los mismos se orientara, por una parte, a procesos catalíticos tecnológicamente innovadores relacionados con los siguientes campos: a)catálisis ambiental: transformación de desechos plásticos (polietileno, polipropileno, poliestireno o mezclas de los mismos) a hidrocarburos de mayor valor agregado (gasolinas, gasoil, gases licuados de petróleo, hidrocarburos aromáticos); b)química fina: oxidación parcial de hidrocarburos aromáticos hacia la obtención de commodities, fármacos, etc. Por otra parte, se evaluaran las propiedades magnéticas (ferromagnetismo, paramagnetismo, superparamagnetismo, diamagnetismo) que algunos de estos materiales presentan, en busca de su correlación con sus propiedades catalíticas, cuando sea factible. Se estudiaran las condiciones óptimas de síntesis de los materiales, aplicando técnicas hidrotermicas o sol gel, controlando variables como temperaturas y tiempos de síntesis, pH de geles iniciales-intermedios-finales, tipo de fuentes precursoras, etc. La modificación de las matrices con Co, Cr, Mn, H, o Zn, se realizara mediante diversos tratamientos químicos (intercambio, impregnación) a partir de las sales correspondientes, con el objeto de incorporar elementos activos al estado iónico, metálico, clusters, etc.; y la influencia de distintos tratamientos térmicos (oxidantes, inertes o reductores; atmósferas dinámicas o estáticas; temperaturas). La caracterización estructural de los materiales será por: AA (cuantificación elemental de bulk); XRD (determinacion de presencia de especies oxidos o metalicas de Zn, Co, Cr, o Mn; determinacion de cristalinidad y estructura); BET (determinacion de area superficial); DSC-TG-DTA (determinacion de estabilidad de las matrices sintetizadas); FTIR de piridina (determinacion de tipo-fuerza-cantidad de sitios activos); Raman y UV-reflectancia difusa (determinacion de especies ionicas interacturando o depositadas sobre las matrices); TPR (identificacion de especies reducibles); SEM-EDAX (determinacion de tamaño de particulas de especies activas y de las matrices y cuanfiticacion superficial); Magnetómetros SQUID y de muestra vibrante (medición de magnetización y susceptibilidad magnética a temperatura ambiente con variación de campo externo aplicado, y variación de temperaturas (4 a 300 K) con campo externo fijo). En síntesis, se plantean tres grandes áreas de trabajo: No1)Síntesis y caracterización de materiales micro y mesoporosos nanoestructurados; No2) Evaluación de las propiedades catalíticas; No3) Evaluación de las propiedades magnéticas. Estos lineamientos nos permitirán generar nuevos conocimientos científicos-tecnológicos, formando recursos humanos (dos becarios posdoctorales; un becario doctoral; tres becarios alumnos de investigación; aproximadamente 15 pasantes de grado al año) aptos para emprender tales desafíos. Los conocimientos originados son constantemente trabajados en las actividades docentes de grado y posgrado que los integrantes del proyecto poseen. Finalmente serán transmitidos y puestos a consideración de pares evaluadores en presentaciones a congresos nacionales e internacionales y revistas especializadas.

Diseño y caracterización de plataformas de biorreconocimiento basadas en el uso de nanoestructuras, biomoléculas y polímeros. Aplicaciones para el desarrollo de (bio)sensores electroquímicos. Design and characterization of biorecognition platforms based on the use of nanostructures, biomolecules and polymers. Applications for the development of electrochemical (bio)sensors.

Los requerimientos de métodos analíticos que permitan realizar determinaciones más eficientes en diversas ramas de la Química, así como el gran desarrollo logrado por la Nanobiotecnología, impulsaron la investigación de nuevas alternativas de análisis. Hoy, el campo de los Biosensores concita gran atención en el primer mundo, sin embargo, en nuestro país es todavía un área de vacancia, como lo es también la de la Nanotecnología. El objetivo de este proyecto es diseñar y caracterizar nuevos electrodos especialmente basados en el uso de nanoestructuras y estudiar aspectos básicos de la inmovilización de enzimas, ADN, aptámeros, polisacáridos y otros polímeros sobre dichos electrodos a fin de crear nuevas plataformas de biorreconocimiento para la construcción de (bio)sensores electroquímicos dirigidos a la cuantificación de analitos de interés clínico, farmaco-toxicológico y ambiental.Se estudiarán las propiedades de electrodos de C vítreo, Au, "screen printed" y compósitos de C modificados con nanotubos de C (CNT) y/o nanopartículas (NP) de oro y/o nanoalambres empleando diversas estrategias. Se investigarán nuevas alternativas de inmovilización de las biomoléculas antes mencionadas sobre dichos electrodos, se caracterizarán las plataformas resultantes y se evaluarán sus posibles aplicaciones analíticas al desarrollo de biosensores con enzimas y ADNs como elementos de biorreconocimiento. Se funcionalizarán CNT con polímeros comerciales y sintetizados en nuestro laboratorio modificados con moléculas bioactivas. Se diseñarán y caracterizarán nuevas arquitecturas supramoleculares basadas en el autoensamblado de policationes, enzimas y ADNs sobre Au. Se evaluarán las propiedades catalíticas de NP de magnetita y de perovskitas de Mn y su aplicación al desarrollo de biosensores enzimáticos. Se diseñarán biosensores que permitan la detección altamente sensible y selectiva de secuencias específicas de ADNs de interés clínico. Se estudiará la interacción de genotóxicos con ADN (en solución e inmovilizado) y se desarrollarán biosensores que permitan su cuantificación. Se construirán biosensores enzimáticos para la cuantificación de bioanalitos, especialmente glucosa, fenoles y catecoles, y sensores electroquímicos para la determinación de neurotransmisores, ácido úrico y ácido ascórbico. Se diseñarán nuevos aptasensores electroquímicos para la cuantificación de biomarcadores, comenzando por lisozima y trombina y continuando con otros de interés regional/nacional.Se emplearán las siguientes técnicas: voltamperometrías cíclica (CV), de pulso diferencial (DPV) y de onda cuadrada (SWV); "stripping" potenciométrico a corriente constante (PSA); elipsometría; microbalanza de cristal de cuarzo con cálculo de pérdida de energía por disipación (QCM-D); resonancia de plasmón superficial con detección dual (E-SPR); espectroscopía de impedancia electroquímica (EIE); microscopías de barrido electroquímico (SECM), de barrido electrónico (SEM), de transmisión (TEM) y de fuerzas atómicas (AFM); espectrofotometría UV-visible; espectroscopías IR, Raman, de masas, RMN.Se espera que la inclusión de los CNT y/o de las NP metálicas y/o de los nanoalambres en los diferentes electrodos permita una mejor transferencia de carga de diversos analitos y por ende una detección más sensible y selectiva de bioanalitos empleando enzimas, ADN y aptámeros como elementos de biorreconocimiento. Se espera una mayor eficiencia en los aptasensores respecto de los inmunosensores, lo que permitirá la determinacion selectiva de diversos biomarcadores. La modificación de electrodos con nanoestructuras posibilitará la detección altamente sensible y selectiva del evento de hibridación. La respuesta obtenida luego de la interacción de genotóxicos con ADN permitirá un mejor conocimiento de la asociación establecida, de la cinética y de las constantes termodinámicas. Los neurotransmisores podrán ser determinados a niveles nanomolares aún en muestras complejas.

Modeling of micro- and nanostructures made of films and crystals/fibers arrays

Magdeburg, Univ., Fak. für Maschinenbau, Diss., 2013