Carbon-dispersed Pt-Rh nanoparticles for ethanol electro-oxidation. Effect of the crystallite size and of temperature

This work presents results of studies of carbon-dispersed Pt-Rh (1:1) nanoparticles as electrocatalysts for the ethanol electro-oxidation. The influences of the crystallite size and the cell temperature on the yields of CO2, acetaldehyde and acetic acid are investigated. Metal nanoparticles were prepared by two different routes: (1) impregnation on carbon powder followed by thermal reduction on hydrogen atmosphere and (2) chemical reduction of the precursor salts. The surface active area and the electrochemical activity of the electrocatalysts were estimated by CO stripping and cyclic voltammetry in the absence and in the presence of ethanol, respectively. Reaction intermediates and products were analyzed by in situ Fourier Transform Infra-Red Spectroscopy (FTIR) and Differential Electrochemical Mass Spectrometry (DEMS). The electrochemical stripping of CO and the electrochemical ethanol oxidation were slightly faster on the Pt-Rh electrocatalysts compared to Pt/C. Also, in situ FTIR spectra and DEMS measurements evidenced that the CO2/acetaldehyde and the CO2/acetic acid ratios are higher for the Pt-Rh/C materials in relation to Pt/C. This was ascribed to the activation of the C-C bond breaking by Rh, this being more prominent for the materials with smaller crystallite sizes. (C) 2008 Elsevier B.V. All rights reserved.

Ethanol electro-oxidation on carbon-supported Pt-Ru, Pt-Rh and Pt-Ru-Rh nanoparticles

This work investigates the effects of carbon-supported Pt, Pt-Ru, Pt-Rh and Pt-Ru-Rh alloy electrocatalysts oil the yields of CO2 and acetic acid as electro-oxidation products of ethanol. Electronic and structural features of these metal alloys were studied by in situ X-ray absorption spectroscopy (XAS). The electrochemical activity was investigated by polarization experiments and the reaction intermediates and products were analyzed by in situ Fourier Transform Infra-Red Spectroscopy (FTIR). Electrochemical stripping of CO. which is one of the adsorbed intermediates, presented a faster oxidation kinetics on the Pt-Ru electrocatalyst, and similar rates of reaction on Pt-Rh and Pt. The electrochemical current of ethanol oxidation showed a higher value and the onset potential was less positive oil Pt-Ru. However, in situ FTIR spectra evidenced that the CO2/acetic acid ratio is higher for the materials with Rh, mainly at lower potentials. These results indicate that the Ru atoms act mainly by providing oxygenated species for the oxidation of ethanol intermediates, and point out ail important role of Rh on the C-C bond dissociation. (C) 2007 Elsevier Ltd. All rights reserved.

Estudo termoanalítico e eletroquímico das reações em estado sólido na interfase metálica dos sistemas Pt-Rh/Hg, empregando a liga de composição Pt-Rh 80:20% (m/m)

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)

Estudo das reações no estado sólido entre a liga de composição 'PT'-'RH'85:15%(m/m) e 'HG'

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)

Estudo termoanalítico e eletroquímico das reações em estado sólido na interfase metálica dos sistemas Pt-Rh/HG, empregando a liga de composição Pt-Rh 70:30% (m/m)

Pós-graduação em Química - IQ

Estudo do comportamento térmico e eletroquímico do sistema 'PT 'RH' 15%- 'HG/CU'

Pós-graduação em Química - IQ

Estudo das reações em estado sólido das ligas Pt-Rh-Tr 70:15:15% (m/m) e Pt-Ir 70:30% com Hg, empregando técnicas eletroquímicas e termoanalíticas

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)

Electro-oxidation of ethanol on Pt/C, Rh/C, and Pt/Rh/C-based electrocatalysts investigated by on-line DEMS

The ethanol electro-oxidation reaction was studied on carbon-supported Pt, Rh, and on Pt overlayers deposited on Rh nanoparticles. The synthesized electrocatalysts were characterized by TEM and XRD. The reaction products were monitored by on-line DEMS experiments. Potentiodynamic curves showed higher overall reaction rate for Pt/C when compared to that for Rh/C. However, on-line DEMS measurements revealed higher average current efficiencies for complete ethanol electro-oxidation to CO2 on Rh/C. The average current efficiencies for CO2 formation increased with temperature and with the decrease in the ethanol concentration. The total amount of CO2, on the other hand, was slightly affected by the temperature and ethanol concentration. Additionally, the CO2 signal was observed only in the positive-going scan, none being observed in the negative-going scan, evidencing that the C-C bond breaking occurs only at lower potentials. Thus, the formation of CO2 mainly resulted from oxidative removal of adsorbed CO and CHx,ad species generated at the lower potentials, instead of the electrochemical oxidation of bulk ethanol molecules. The acetaldehyde mass signal, however, was greatly favored after increasing the ethanol concentration from 0.01 to 0.1 mol L-1, on both electrocatalysts, indicating that it is the major reaction product. For the Pt/Rh/C-based electrocatalysts, the Faradaic current and the conversion efficiency for CO2 formation was increased by adjusting the amount of Pt on the surface of the Rh/C nanoparticles. The higher conversion efficiency for CO2 formation on the Pt1Rh/C material was ascribed to its faster and more extensive ethanol deprotonation on the Pt-Rh sites, producing adsorbed intermediates in which the C-C bond cleavage is facilitated. (C) 2012 Elsevier B.V. All rights reserved.

Insight into the key aspects of the regeneration process in the NOx storage reduction (NSR) reaction probed using fast transient kinetics coupled with isotopically labelled (NO)-N-15 over Pt and Rh-containing Ba/Al2O3 catalysts

For the first time, the coupling of fast transient kinetic switching and the use of an isotopically labelled reactant (15NO) has allowed detailed analysis of the evolution of all the products and reactants involved in the regeneration of a NOx storage reduction (NSR) material. Using realistic regeneration times (ca. 1 s) for Pt, Rh and Pt/Rh-containing Ba/Al2O3 catalysts we have revealed an unexpected double peak in the evolution of nitrogen. The first peak occurred immediately on switching from lean to rich conditions, while the second peak started at the point at which the gases switched from rich to lean. The first evolution of nitrogen occurs as a result of the fast reaction between H2 and/or CO and NO on reduced Rh and/or Pt sites. The second N2 peak which occurs upon removal of the rich phase can be explained by reaction of stored ammonia with stored NOx, gas phase NOx or O2. The ammonia can be formed either by hydrolysis of isocyanates or by direct reaction of NO and H2.

The study highlights the importance of the relative rates of regeneration and storage in determining the overall performance of the catalysts. The performance of the monometallic 1.1%Rh/Ba/Al2O3 catalyst at 250 and 350 °C was found to be dependent on the rate of NOx storage, since the rate of regeneration was sufficient to remove the NOx stored in the lean phase. In contrast, for the monometallic 1.6%Pt/Ba/Al2O3 catalyst at 250 °C, the rate of regeneration was the determining factor with the result that the amount of NOx stored on the catalyst deteriorated from cycle to cycle until the amount of NOx stored in the lean phase matched the NOx reduced in the rich phase. On the basis of the ratio of exposed metal surface atoms to total Ba content, the monometallic 1.6%Pt/Ba/Al2O3 catalyst outperformed the Rh-containing catalysts at 250 and 350 °C even when CO was used as a reductant.

Electrocatalysis of ethanol oxidation on Pt monolayers deposited on carbon-supported Ru and Rh nanoparticles

Pt monolayers deposited on carbon- supported Ru and Rh nanoparticles were investigated as electrocatalysts for ethanol oxidation. Electronic features of the Pt monolayers were studied by in situ XANES (X-ray absorption near-edge structure). The electrochemical activity was investigated by cyclic voltammetry and cronoamperometric experiments. Spectroscopic and electrochemical results were compared to those obtained on carbon-supported Pt-Ru and Pt-Rh alloys, and Pt E-TEK. XAS results indicate a modification of the Pt 5d band due to geometric and electronic interactions with the Ru ant Rh substrates, but the effect of withdrawing electrons from Pt is less pronounced in relation to that for the corresponding alloys. Electrochemical stripping of adsorbed CO, which is one of the intermediates, and the currents for the oxidation of ethanol show faster kinetics on the Pt monolayer deposited on Ru nanoparticles, and an activity that exceeds that of conventional catalysts with much larger amounts of platinum. (c) 2007 Elsevier B.V. All rights reserved.

Thermal and electrochemical study of solid-state reaction of mercury with Pt-20% Rh alloy

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)

Electrocatalytic Activity of Pd, Pt, and Rh for the Electro-oxidation of Ethanol in Alkaline Electrolyte: An Online DEMS Study

The electro-oxidation of ethanol was investigated on electrodeposited layers of Pd, Pt, and Rh in alkaline electrolyte. The reaction products were monitored by experiments of online differential electrochemical mass spectrometry (DEMS). Potentiodynamic curves for the ethanol electro-oxidation catalyzed by these three different metal electrocatalysts showed similar onset potentials, but the highest Faradaic current peak was observed for the Pt electrocatalyst. Online DEMS experiments evidenced similar amounts of CO2 for the three different materials, but Pd presented the higher production of ethylacetate (acetic acid). This indicated that the electrochemical oxidation of ethanol on the Pd surface occurred to a higher extent. The formation of methane, which was observed for Pt and Rh, after potential excursions to lower potentials, was absent for Pd. On the basis of the obtained results, it was stated that, on Pt and Rh, the formation of CO2 occurs mainly via oxidation of CO and CH (x,ad) species formed after dissociative adsorption of ethanol or ethoxy species that takes place only at low potentials. This indicates that the dissociative adsorption of ethanol or ethoxy species is inhibited at higher potentials on Pt and Rh. On the other hand, on the Pd electrocatalyst, the reaction may occur via nondissociative adsorption of ethanol or ethoxy species at lower potentials, followed by oxidation to acetaldehyde and, after that, by a further oxidation step to acetic acid on the electrocatalyst surface. Additionally, in a parallel route, the acetaldehyde molecules adsorbed on the Pd surface can be deprotonated, yielding a reaction intermediate in which the carbon-carbon bond is less protected, and therefore, it can be dissociated on the Pd surface, producing CO2, after potential excursions to higher potentials.

Sn@Pt and Rh@Pt core–shell nanoparticles synthesis for glycerol oxidation

The development and optimization of electrocatalysts for application in fuel cell systems have been the focus of a variety of studies where core–shell structures have been considered as a promising alternative among the materials studied. We synthesized core–shell nanoparticles of Sn x @Pt y and Rh x @Pt y (Sn@Pt, Sn@Pt2, Sn@Pt3, Rh@Pt, Rh@Pt2, and Rh@Pt3) through a reduction methodology using sodium borohydride. These nanoparticles were electrochemically characterized by cyclic voltammetry and further analyzed by cyclic voltammetry studying their catalytic activity toward glycerol electro-oxidation; chronoamperometry and potentiostatic polarization experiments were also carried out. The physical characterization was carried out by X-ray diffraction, energy-dispersive X-ray spectroscopy, X-ray photoelectron spectroscopy, and transmission electron microscopy. The onset potential for glycerol oxidation was shifted in 130 and 120 mV on the Sn@Pt3/C and Rh@Pt3/C catalysts, respectively, compared to commercial Pt/C, while the stationary pseudo-current density, taken at 600 mV, increased 2-fold and 5-fold for these catalysts related to Pt/C, respectively. Thus, the catalysts synthesized by the developed methodology have enhanced catalytic activity toward the electro-oxidation of glycerol, representing an interesting alternative for fuel cell systems.

稀土墩子和稀土氧化物对甲醇在Pt催化剂上电催化氧化性能的影响

直接甲醇燃料电池( DMFC )具有甲醇来源丰富，价格低廉，在常温常压下是液体，易于携带储存；体积小，重量轻，结构简单，容易操作；维修方便，价格低等优点，近年来得到普遍的关注。然而，要达到DMFC的商品化还存在一些问题。其中一个是阳极催化剂的电催化活性低和易被甲醇氧化的中间产物，如CO毒化。对于甲醇阳极电催化剂人们进行了大量的研究，比较有效的都是Pt－过渡金属或金属氧化物复合催化剂，如Pt－Ru、 Pt－Sn、Pt佩Rh、Pt－Pd、Pt佩Re、Pt－Ru－Sn－W、Pt－WO。和Pt－TIO。等。本文研究了电解液中的稀土离子和与Pt形成复合催化剂的稀土氧化物对甲醇电催化氧化反应的促进作用，得到了如下的结果：1．电解液中的稀土Ho, Eu, Gd或Dy离子对甲醇在光滑Pt电极或DMFC中使用的Pt/C电极上的电催化氧化反应有促进作用，主要表现在的起始氧化电位负移和氧化电流增加。而电解液中加入其它种类的稀土离子对甲醇在光滑Pt电极或Pt/C电极上的电催化氧化反应有阻碍作用，如起始氧化电位正移，峰电流降低。Fu、H食Dy或Gd离子对一甲醇在Pt上的电催化氧化反应有促进作用的主要原因可能与这些稀土离子与甲醇生成配合物能力有关。2．不同Pt一稀土氧化物／C催化剂对甲醇电催化氧化反应有不同的影响。当稀土氧化物是Eu, Ho, Dy或Gd的氧化物时，甲醇在Pt一稀土氧化物／C催化剂上甲醇电催化氧化反应的极化性能和稳定性要优于在Pt/C催化剂上，而在其它的Pt-稀土氧化物／C催化剂上，甲醇电催化氧化的极化性能和稳定性要差于Pt/C电极。用不同方法制备的Pt一稀土氧化物／C催化剂对甲醇电催化氧化反应的促进作用取决于催化剂的制备方法。如先在活性碳上还原沉积Pt，再沉积上稀土氧化物所得的Pt－稀土氧化物／C催化剂的促进作用要优于先在稀土氧化物上还原沉积Pt，再一起沉积到活性碳上或先再活性碳上沉积稀土氧化物，再还原沉积上Pt的方法。另外，Pt和稀上氧化物的原子比为2：1时，pt－稀土氧化物／c催化剂对甲醇电催化氧化反应的催化活性最佳。稀土氧化物对pt／C催化剂对甲醇氧化反应的电催化性质的影响与稀土离子相似。但用稀土离子的方法比较简便，因此，相比之下，用稀土离子来促进甲醇在Pt上的电催化氧化反应方法较好。3．用Eu, Gd, Dy, Ho的氧化物制得的Pt-稀土氧化物／C复合催化剂对co的电催化氧化反应的催化活性要高于Pt/C催化剂。相对于的情况，在co在Eu, Gd, Dy,Ho的氧化物的Pt／稀土氧化物／C复合催化剂电极上的循环伏安图中，CO的氧化峰峰电位比在Pt/C电极的有不同程度的负移。吸．初步确定了电极和单体电池制备的较好的工艺参数和工作条件。在发明一种薄电极制备方法，确定最佳的电极催化层配方等的基础上，制得的单体电池，在25℃工作时，输出功率密度峰值达到28 mW/cm~2。

Estudo das reações em estado sólido dos sistemas 'PT' - 6% e 'PT' - 10% 'IR' na ausência e presença de 'HG'

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)