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81	Electronic structure dependence on molecular orientation: a Scanning Tunneling Microscopy study of C60 on Cu(100) Daughton, David 17 December 2010 (has links) No description available. Physics scanning tunneling microscopy C60 fullerene molecular electronics
82	Supramolecular organisation, conformation and electronic properties of porphyrin molecules on metal substrates Weber, Alexander 05 1900 (has links) The investigation and control of molecular properties is currently a dynamic research field. Here I present molecular level studies of porphyrin molecules adsorbed on metal surfaces via Low Temperature Scanning Tunneling Microscopy/Spectroscopy (STM/STS), supported by complementary X-ray absorption experiments. Intermolecular and molecule-surface interactions of tetrapyrdil porphyrin (TPyP) on Ag(111) and Cu(111) were investigated. TPyP self-assembles on Ag(111) over a wide sample temperature range into large, highly-ordered 2D chiral domains. By contrast, adsorption of TPyP on the more reactive Cu(111) leads to temperature dependent assemblies, governed decisively by the strong substrate influence. The increased metal-surface interactions on Cu(111) are accompanied by a conformational distortion of the porphyrin macrocycle. The TPyP’s pyridil groups were coordinated with single iron molecules, forming metal-organic complexes. Furthermore, the porphyrin’s macrocycle was metalated by exposing a layer of well-ordered TPyP to an iron atom beam, demonstrating a novel approach towards the fabrication of metallo-tetraaryl porphyrins performed in two dimensions under ultrahigh vacuum conditions. This method was similarly used to form lanthanideporphyrinates by coordinating tetraphenyl porphyrin (TPP) macrocycles with cerium. The influence of the metal center on the porphyrins’ electronic structure was investigated via STS for TPP, TPyP,Fe−TPyP, Fe−TPP, Ce−TPP, and Co−TPP, whereby the inhomogenous electron density distribution associated with individual frontier orbitals were imaged via dI/dV mapping. The symmetry and form of the molecular orbitals could be directly correlated to the saddle-shaped conformational adaptation for the case of Co −TPP. supramolecular nanostructures electronic structure molecules molecular conformation Scanning Tunneling Microscopy Scanning Tunneling Microscopy porphyrin metalation electronic properties molecular manipulation
83	Supramolecular organisation, conformation and electronic properties of porphyrin molecules on metal substrates Weber, Alexander 05 1900 (has links) The investigation and control of molecular properties is currently a dynamic research field. Here I present molecular level studies of porphyrin molecules adsorbed on metal surfaces via Low Temperature Scanning Tunneling Microscopy/Spectroscopy (STM/STS), supported by complementary X-ray absorption experiments. Intermolecular and molecule-surface interactions of tetrapyrdil porphyrin (TPyP) on Ag(111) and Cu(111) were investigated. TPyP self-assembles on Ag(111) over a wide sample temperature range into large, highly-ordered 2D chiral domains. By contrast, adsorption of TPyP on the more reactive Cu(111) leads to temperature dependent assemblies, governed decisively by the strong substrate influence. The increased metal-surface interactions on Cu(111) are accompanied by a conformational distortion of the porphyrin macrocycle. The TPyP’s pyridil groups were coordinated with single iron molecules, forming metal-organic complexes. Furthermore, the porphyrin’s macrocycle was metalated by exposing a layer of well-ordered TPyP to an iron atom beam, demonstrating a novel approach towards the fabrication of metallo-tetraaryl porphyrins performed in two dimensions under ultrahigh vacuum conditions. This method was similarly used to form lanthanideporphyrinates by coordinating tetraphenyl porphyrin (TPP) macrocycles with cerium. The influence of the metal center on the porphyrins’ electronic structure was investigated via STS for TPP, TPyP,Fe−TPyP, Fe−TPP, Ce−TPP, and Co−TPP, whereby the inhomogenous electron density distribution associated with individual frontier orbitals were imaged via dI/dV mapping. The symmetry and form of the molecular orbitals could be directly correlated to the saddle-shaped conformational adaptation for the case of Co −TPP. supramolecular nanostructures electronic structure molecules molecular conformation Scanning Tunneling Microscopy Scanning Tunneling Microscopy porphyrin metalation electronic properties molecular manipulation
84	Supramolecular organisation, conformation and electronic properties of porphyrin molecules on metal substrates Weber, Alexander 05 1900 (has links) The investigation and control of molecular properties is currently a dynamic research field. Here I present molecular level studies of porphyrin molecules adsorbed on metal surfaces via Low Temperature Scanning Tunneling Microscopy/Spectroscopy (STM/STS), supported by complementary X-ray absorption experiments. Intermolecular and molecule-surface interactions of tetrapyrdil porphyrin (TPyP) on Ag(111) and Cu(111) were investigated. TPyP self-assembles on Ag(111) over a wide sample temperature range into large, highly-ordered 2D chiral domains. By contrast, adsorption of TPyP on the more reactive Cu(111) leads to temperature dependent assemblies, governed decisively by the strong substrate influence. The increased metal-surface interactions on Cu(111) are accompanied by a conformational distortion of the porphyrin macrocycle. The TPyP’s pyridil groups were coordinated with single iron molecules, forming metal-organic complexes. Furthermore, the porphyrin’s macrocycle was metalated by exposing a layer of well-ordered TPyP to an iron atom beam, demonstrating a novel approach towards the fabrication of metallo-tetraaryl porphyrins performed in two dimensions under ultrahigh vacuum conditions. This method was similarly used to form lanthanideporphyrinates by coordinating tetraphenyl porphyrin (TPP) macrocycles with cerium. The influence of the metal center on the porphyrins’ electronic structure was investigated via STS for TPP, TPyP,Fe−TPyP, Fe−TPP, Ce−TPP, and Co−TPP, whereby the inhomogenous electron density distribution associated with individual frontier orbitals were imaged via dI/dV mapping. The symmetry and form of the molecular orbitals could be directly correlated to the saddle-shaped conformational adaptation for the case of Co −TPP. / Science, Faculty of / Physics and Astronomy, Department of / Graduate supramolecular nanostructures electronic structure molecules molecular conformation Scanning Tunneling Microscopy Scanning Tunneling Microscopy porphyrin metalation electronic properties molecular manipulation
85	Kinetic and Morphological Studies of Pd Oxidation in O2-CH4 mixtures Han, Jinyi 29 April 2004 (has links) The oxidation of Pd single crystals: Pd(111), Pd(100) and Pd(110) was studied using Temperature Programmed Desorption (TPD), X-ray Photoelectron Spectroscopy (XPS), Auger Electron Spectroscopy (AES), Low Electron Energy Diffraction (LEED) and Scanning Tunneling Microscopy (STM) as they were subjected to O2 in the pressure range between 1 and 150 Torr at temperatures 600-900 K. The oxygen species formed during oxidation, the oxygen uptake dependence on the sample history, the Pd single crystal surface morphology transformations, and the catalytic methane combustion over Pd single crystals were investigated in detail. The Pd single crystal oxidation proceeded through a three-step mechanism. Namely, (1) oxygen dissociatively adsorbed on Pd surface, forming chemisorbed oxygen and then surface oxide; (2) atomic oxygen diffused through a thin surface oxide layer into Pd metal, forming near surface and bulk oxygen; (3) bulk PdO formed when a critical oxygen concentration was reached in the near surface region. The diffusion of oxygen through thin surface oxide layer into Pd metal decreased in the order: Pd(110)>Pd(100)>Pd(111). The oxygen diffusion coefficient was estimated to be around 10-16 cm2 s-1 at 600 K, with an activation energy of 80 kJ mol-1. Once bulk PdO was formed, the diffusion of oxygen through the bulk oxide layer was the rate-determining step for the palladium oxidation. The diffusion coefficient was equal to 10-18 cm2 s-1 at 600 K and the activation energy was approximately 120 kJ mol-1. The oxygen diffusion through thin surface oxide layer and bulk PdO followed the Mott-Cabrera parabolic diffusion law. The oxygen uptake on Pd single crystals depended on the sample history. The uptake amount increased with the population of the bulk oxygen species, which was achieved by high oxygen exposure at elevated temperatures, for example in 1 Torr O2 at above 820 K. Ar+ sputtering or annealing in vacuum at 1300 K depleted the bulk oxygen. The Pd single crystal surface morphology was determined by the oxidation conditions: O2 pressure, treatment temperature and exposure time. When bulk PdO was formed, the single crystal surface was covered with semi-spherical agglomerates 2-4 nm in size, which tended to aggregate to form a“cauliflower-like" superstructure. The single crystal surface area during oxidation, determined by integrating the STM image, experienced three major expansions in consistent with a three-step oxidation mechanism. The surface area on the oxidized single crystals increased in the order: Pd(110) Oxidation Paladium Scanning Tunneling Microscopy Palladium oxide PdO morphology PdO surface area measurement Turnover rate for methane combustion Oxygen Palladium Oxidation Scanning tunneling microscopy
86	Structural and spectroscopic studies of surfaces Laitenberger, Peter January 1996 (has links) No description available. 530.41
87	Atomic force microscopy : atomic resolution imaging and force-distance spectroscopy Grimble, Ralph Ashley January 1999 (has links) No description available. 535
88	Imaging and manipulation of atoms by STM at room temperature Fishlock, Timothy William January 1998 (has links) No description available. 530.41
89	Structural and spectroscopic studies of surfaces on the nanometre scale Festy, Frederic January 2000 (has links) No description available. 530.41
90	Structure and Electronic Properties of Phthalocyanine Films on Metal and Semiconductor Substrates / Structure et propriétés électroniques de films phthalocyanine sur Substrats métalliques et Semi-conducteurs Bidermane, Ieva 14 March 2014 (has links) Cette thèse présente des résultats originaux sur les phtalocyanines (Pc), un groupe de molécules d'inspiration biologique. En raison de l'utilisation grandissante de films moléculaires de phtalocyanine dans des dispositifs ayant des applications technologiques variées, de nombreuses études ont été consacrées à ces molécules au cours des dernières décennies.Les spectroscopies de photoélectron sur les niveaux de c¿ur ou de valence (PES), la spectroscopie d'absorption des rayons X (XAS) et la microscopie à effet tunnel (STM) ont été utilisées pour étudier ces molécules en phase gazeuse et adsorbées sur l'or Au (111) et le silicium Si (100)-2x1 . Des calculs théoriques utilisant la fonctionnelle de la densité (DFT) sont utilisés pour obtenir des informations complémentaires sur leur structure électronique. Le but de nos études est d'obtenir une meilleure compréhension des interactions molécule - molécule et molécule - surface, pour améliorer les dispositifs à base de phtalocyanine.Grâce à des calculs DFT et des mesures PSE en phase gazeuse, il a été possible de mettre en évidence l'influence de l'ion métallique sur la bande de valence. Ainsi FePc présente les états 2p du carbone alors que ce sont les états 3d du manganèse qui dominent pour MnPc. Les études PES et STM sur H2Pc et LuPc2 déposés sur Au (111) ont révélé la formation de monocouche et de bicouche respectivement. La comparaison entre l'adsorption de LuPc2 sur Si(100) nu ou passivé a confirmé la différence de réactivité sur ces deux surfaces : sur Si passivé, LuPc2 conserve un caractère moléculaire, en revanche sur Si nu, une interaction importante est mise en évidence. / The thesis presents fundamental studies of phthalocyanines (Pc), a group of organic macro-cycle molecules, similar to systems found in nature. The use of phthalocyanine molecular films in devices with a variety of possible technological applications has been the reason of the many studies during the last decades. Core and valence photoelectron spectroscopies (PES), X-ray absorption spectroscopy (XAS) and scanning tunneling microscopy (STM) techniques are used to study Pc molecules in gas phase and adsorbed on gold Au(111) and silicon Si(100)-2x1 substrates. Density function theory (DFT) is used to obtain further insights in the electronic structure of the phthalocyanines.We aim to obtain a deeper understanding of the molecule-molecule and molecule-substrate interactions, a fundamental requirement for improving devices based on organic materials. Gas phase PES experiments and DFT calculations performed on different Pcs show the influence of the metal atom on the valence band spectra, where FePc and H2Pc HOMO is formed from C2p states, whereas MnPc has mainly Mn3d character.PES and STM studies of H2Pc and LuPc2 on Au(111) show a formation of a monolayer for H2Pc and a bi-layer of LuPc2 at lower thicknesses. XAS studies show a parallel to surface orientation of both H2Pc and LuPc2 with a change in tilt angle of the molecules with increasing thickness.A comparison of LuPc2 adsorbed on pristine and passivated Si surfaces show a bulk-like LuPc2 character on passivated Si, whereas a surface induced difference in adsorption geometry is evidenced on pristine Si and two energetically different adsorption geometries are proposed. Structure électronique Phtalocyanines Microscopie à effet tunnel Spectroscopie de photoélectron Auto-organisation Silicium Scanning tunneling microscopy Phthalocyanines 530

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