Transition metal clusters on h-BN/Rh(111)

The main aim of this dissertation is to study the catalytic aspects of very small transition metal clusters supported on h-BN/Rh(111). The catalytic reactions of interest were ammonia synthesis and CO oxidation on mass selected and soft landed iron and platinum clusters, respectively. A special focus was devoted to the investigation of the stability of these very small clusters on h-BN before and after the reaction. It was found that Pt7 clusters soft landed at room temperature with an energy of 1.2 eV per atom and annealed to 700 K exhibit Smoluchowski ripening. Above this temperature, these clusters undergo partial intercalation between the h-BN monolayer and the Rh(111). The intercalation initiates at 900 K and becomes more pronounced when the clusters are annealed under gas reaction conditions. A high catalytic activity was observed when the Pt catalyst remains supported on h-BN. In this case, the reaction starts at 480 K and follows Langmuir-Hinshelwood mechanism. However, the catalytic activity strongly reduces when the Pt clusters undergo partial intercalation. Nevertheless, in this case the reaction starts at only 380 K, revealing a reduction by 100 K in the Pt poisoning as a result of substrate effect and charge redistribution. In a second trail, the cluster-h-BN interaction was studied through h-BN irradiation with Pt clusters, at room temperature, within an energy window of 30-416 eV/atom. The results show that even irradiation at 30 eV/atom can lead to entire non thermal intercalation of the clusters. The energetic Pt clusters were found to be site selective as they settle only under the h-BN wires, in contrast to soft landed Pt7 clusters that were found to settle at the side edge of the h-BN depressions. After being exposed to irradiated Pt clusters, at an energy above 100 eV/atom, the h-BN layer starts to display visual cavity-type defects. These defects, induced by collision, disappeared after annealing to 600 K under gas reaction leaving behind an h-BN with no visual defects. CO temperature desorption spectroscopy (TDS) indicates that the intercalated Pt is inactive towards CO oxidation due to h-BN screening. Subsequently, we were able to produce a catalyst system made of soft-landed Pt/h-BN/intercalated Pt/Rh(111) using a combination between soft and energetic Pt deposition with which a reduction by 100 K in CO poisoning was obtained. Finally, ammonia synthesis was conducted on soft landed Fe clusters, supported on h-BN/Rh(111) and deposited at 100 K under Ultra High Vacuum (UHV). Scanning tunneling microscopy (STM) displays two imaging states of the as deposited clusters; a ring state surrounding h-BN depression which disappears above 300 K and a dot like structure. The Fe clusters are found to grow by Ostwald ripening after annealing to 600 K and above this temperature, they endure partial intercalation. It was found that, in the presence of iron, the nitrogen reaction gas experienced an exchange with the nitrogen species forming the h-BN layer. TPR (Temperature Programmed Reduction) of N $_2$ with hydrogen revealed that nitrogen reduction occurs at 620 K under high vacuum following the Haber-Bosch method. The detection of reaction intermediates NH and NH $_2$ together with desorbed atomic nitrogen, during ammonia synthesis, confirms that NH $_3$ formation involves the stepwise hydrogenation of adsorbed nitrogen.

Cluster-Surface Interaction and Catalytic Activity

Simon Bonanni

This thesis is devoted to the study of the catalytic activity of small supported metal clusters. The TiO2(110)-(1×1) supported platinum cluster activity towards CO oxidation, its correlation with the cluster morphology, support properties, and the cluster stability are studied. For this purpose a new ultra-high vacuum (UHV) compatible reactor has been developed, which, in combination with a low temperature scanning tunneling microscope, a size selected cluster source and standard techniques for sample preparation, constitutes a unique experimental setup that allows for in situ investigations of the morphology and catalytic properties of size-selected cluster based model catalysts. First, large platinum clusters (100 to 200 atoms per cluster), grown from deposited atoms, were investigated. This system initially shows a low catalytic activity, due to the formation of a TiOx (0 < x < 2) encapsulation layer on the clusters upon annealing, known as strong metal-support interaction (SMSI) state. We observed that a soft sputtering and a second annealing to 1100 K give rise to a highly active catalyst for CO oxidation. We attribute the activation of the catalytic activity to the destruction of the encapsulation layer by the soft sputtering and to the absence of its reformation during the second annealing. This procedure could in principle be used to activate other initially passive SMSI systems. Second, the effect of the reduction state of the TiO2 support on the catalytic activity of the supported Pt clusters has been analyzed. It is demonstrated that small platinum clusters (in this case Pt7) are two orders of magnitude more active toward CO oxidation when they are supported on slightly reduced TiO2 crystals than when they are supported on strongly reduced ones. This is attributed to the consumption of the oxygen absorbed on the surface by the crystal interstitial titanium atoms, which are present in higher concentration in strongly reduced crystals than in weakly reduced ones. The effect could take place also for other catalytic processes involving oxygen on TiO2 supported metal clusters and allow for the tuning of oxidation and de-oxidation reactions. Platinum cluster size effects on the catalytic CO oxidation have been investigated depositing Pt3, Pt7 and Pt10 clusters on TiO2(110)-(1×1). From Pt3 clusters a CO2 production, per platinum atom, two times bigger than the one from Pt7 and Pt10 has been observed. The cluster morphology was strongly modified by the exposure to the reaction environment (temperatures up to 600 K and CO and O2 doses). This highlights the necessity to study the stability of small platinum clusters as a function of the temperature and gas exposure. Finally, as suggested by the preceding measurements, the stability of Pt7 clusters on TiO2 has been investigated as a function of the temperature, from 300 K to 600 K, and of the exposure to gases. Pt7 clusters are proved to be stable in UHV up to 430 K on the TiO2(110)-(1×1) surface. If the annealing is performed while exposing the sample to gases (CO, O2 and a mixture of the two) important cluster sintering takes place already at 430 K. This effect can be attributed to a modification of the cluster-support interaction induced by the adsorption of gases and to the additional energy injected in the system by the CO combustion taking place on the clusters when both CO and O2 are dosed.

EPFL2012

Développement d'un réacteur microstructuré basé sur des filaments métalliques catalytiques

Chrystèle Horny

The aim of this work is to develop a microstructured reactor based on filamentous catalysts for the Oxidative Steam-Reforming of Methanol (OSRM), to produce hydrogen as feed for a fuel cell, in an autothermal way. Hydrogen is produced by the methanol Steam-Reforming (SR) reaction. This endothermic reaction requires an external heat source which is, in our case, generated by methanol oxidation. The coupling of these two reactions – SR and oxidation, called oxidative steam-reforming of methanol – is performed in a single reactor. As the oxidation is much faster than SR, it occurs in the first part of the reactor, the SR takes place in the second part. If a conventional fixed bed reactor is used, pronounced axial temperature profiles are developed: a hot–spot due to the exothermicity of the oxidation is generated at the entrance followed by a cold–spot due to the SR. The high temperature may damage the catalyst and the low temperature diminishes the rate of reforming reaction leading to poor reactor performance. Thus the temperature control is crucial. Consequently, a microstructured reactor is used. This kind of reactor has multiple parallel channels with a diameter ranging from ten to several hundreds micrometers. These submillimetric dimensions lead to a high surface to volume ratio and a much higher heat transfer coefficient than in the traditional heat exchangers. These characteristics allow to increase heat exchange between reactions and to avoid hot–spot formation. In this work, brass wires introduced into a macro tubular reactor parallel to the walls are used to create the microstructure. Brass is chosen because of its composition – it contains copper and zinc catalyzing the reforming/oxidation of methanol – and for its high heat conductivity which ensures heat exchange improvements. Moreover the small diameter of reactor channels ensures narrow residence time distribution, leading to high selectivity, and a short residence time, improving reactors dynamic. The characteristics mentioned above are verified in chapter 4 for the reactor developed during this study. The hydrodynamic of this reactor is presented under the influence of wire diameter and catalyst preparation treatment. The flow in the microstructure is close to a plug flow: a Bodenstein number of 105 is obtained for brass wires with a diameter of 480μm. Concerning catalytic treatment, it doesn't appear to modify the hydrodynamic. Compared to a fixed bed reactor, the measured residence time distribution for our microstructured reactor is found to be much narrower; the pressure drops are also smaller. Chapter 5 focuses on the reaction conditions for SR of methanol, the reaction that generates hydrogen. These conditions are determined by using an industrial catalyst (based on copper –zinc – aluminium) and by comparing the catalytic activity measured in our conditions with the ones found in the literature. A molar water to methanol ratio of 1.2 is chosen in order to avoid carbon monoxide production, which is a poison for fuel cells. Chapter 6 deals with the development, the optimisation and the characterisation of brass based catalyst. Brass grids are first tested for SR: alloy composition, type and time of leaching are studied. The optimal catalyst is found to be a CuZn37 grid incorporated with aluminium and treated by an acid leaching during 20 minutes in order to increase its surface area (30m2/g). In order to test brass activity in presence of oxygen, partial oxidation of methanol is first carried out over this catalyst. Then the oxidative steam-reforming of methanol is studied: it is found that the modification of the support and hence of the treatment applied decreases the activity and essentially the stability. Deactivation is attributed to copper particles sintering and to oxidation of the catalyst which is not active for hydrogen production. A screening of additives is performed and it is shown that brass wires incorporated with aluminium and doped with chromium by an impregnation method is active, stable and selective: methanol conversion of 25.3% with a hydrogen selectivity of 42.6% are maintained during more than ten hours. Analyses indicate that this catalyst is not easily oxidised and reduced, due to the presence of spinels on the surface which modify electronic properties of copper. In chapter 7, the OSRM is analysed with focus on reaction mechanism and heat exchange. The reaction mechanism is quite complex due to reactions involved (partial oxidations, total oxidation, decomposition) and to their strong temperature dependence. A production of formaldehyde is observed at low temperature (T < 240°C), whereas at higher temperatures secondary reactions disappear and hydrogen production is initiated. Finally, measurements of the axial temperature profile allow to verify the isothermicity of our microstructured reactor: for a methanol conversion of 43% at T = 262°C a hot–spot of less than 3.5°C is measured and no cold–spot is observed. However, it is shown that the temperature profile is highly influenced by methanol conversion and by the oxygen quantity introduced in the reactor. Temperature variations in the entire reactor are nevertheless much lower than those developed in a fixed bed reactor, which is in agreement with our expectations and corresponds to our pursued objectives.

EPFL2005

Cluster-Surface Interaction and Catalytic Activity

Simon Bonanni

EPFL2012

Développement d'un réacteur microstructuré basé sur des filaments métalliques catalytiques

Chrystèle Horny

EPFL2005