Estrutura eletrônica de melaninas solvatadas / Electronic structure of solvated melanins

Autreto, Pedro Alves da Silva, 1983-

03 February 2007

Orientador: Douglas Soares Galvão / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Fisica Gleb Wataghin / Made available in DSpace on 2018-08-09T02:37:49Z (GMT). No. of bitstreams: 1 Autreto_PedroAlvesdaSilva_M.pdf: 14908796 bytes, checksum: 389f8f28e3d38fbfe32aeab511893f6e (MD5) Previous issue date: 2007 / Resumo: As melaninas constituem uma classe de pigmentos biológicos de destaque devido, sobretudo, a sua predominante presença nos tecidos dos mamíferos. Há fortes evidências que sugerem que a pigmentação por melanina tem por objetivo proteger a pele contra efeitos prejudiciais da radiação ultravioleta. Além deste papel de fotoproteção, outras funções biológicas são especuladas em razão da presença do pigmento em regiões não iluminadas do corpo como por exemplo no cérebro em que há uma aparente destruição preferencial das células que contém melanina quando ocorrem doenças como o mal de Parkinson. Apesar de décadas de investigações, nenhuma amostra de melanina foi estruturalmente bem caracterizada. Dentre os diversos obstáculos que são responsáveis pelo lento progresso que marca a pesquisa deste pigmento, o maior deles é que as melaninas naturais são altamente insolúveis e de presumido alto peso molecular. Pesquisas recentes desenvolvem sínteses alternativas para as melaninas utilizando outros solventes e demonstram que até 20 % da estrutura desta pode ser composta por água. Assim, neste trabalho investigamos, por métodos quânticos, a geometria e estrutura eletrônica das moléculas 5,6 indolquinona, suas formas reduzidas (semiquinona e hidroquinona) e 27 dímeros obtidos a partir destas, em seus estados neutros e iônicos ( ± 1 e ± 2), no vácuo e nos solventes DMF(dimetilformamida), DMSO (dimetilsulfóxido) e água. Verificamos como o solvente altera as propriedades eletrônicas e espectroscópicas destas estruturas e como este pode ser fundamental para a determinação de suas geometrias. Utilizamos dois modelos para simular o solvente: um modelo contínuo, COSMO (Conductor-like Screening Model) e um discreto, que considera explicitamente cada molécula do solvente e é baseado em simulações Monte Carlo. Notamos que o solvente altera a propriedade de aceitador de dois elétrons de diversas estruturas, fato até então não observado e de importante consequência biológica, visto as eumelaninas poderem ser base de um mecanismo de defesa celular contra radicais livres. Os picos dos espectros de absorção, de um modo geral, são deslocados para o vermelho e, em alguns casos, tem um alargamento. Isto poderia contribuir para a constrção da larga banda característica das eumelaninas. Diversos outros aspectos importantes, em excelente acordo com dados experimentais, são também apresentados ao se considerar o solvente. Um dos mais relevantes mostra que o solvente tem forte influência na geometria da molécula com o menor custo de dimerização, o que nos leva a concluir que esta pode ser de fato a semente de "nucleação" para a formação do polímero de melanina. / Abstract: Melanins belong to an important class of biological pigments due to its abundant presence in mamal tissues. There are strong evidences that suggest that the pigmentation due to melanin would protect the skin against the biochemical devastation induced by solar exposure. Besides the photo-protection feature, other biological functions have been speculated to melanin due to its presence in non-illuminated areas of the body and the apparent preferential destruction of melanin-containing cells in the substancia nigra of the brain in Parkinsonism. Unfortunately, in what concerns structural and chemical composition, no melanin sample has been fully and unambiguously characterized yet, despite the enormous amount of experimental work done so far. The main difficulty for that is that melanin is insoluble in most organic solvents and has high molecular weight. A new synthetic route for melanins, using organic solvents, has been recently achieved and it was demonstrated that about 20 % of the structure of the pigment is composed by water. In this work we have investigated using quantum methods the geometries and electronic structure of 5,6 indolquinone, their redox forms (semiquinone and hidroquinone) and 27 dimers associated, in their neutral and ionic states ( ± 1 e ± 2). The calculation were carried in vacuum and in the solvents dimethyl sulfoxide (DMSO), N,N-dimethyl formamide (DMF) and water. We study the effect of the solvent on the electronic and spectroscopic properties and its importance to determine eumelanin structure. Two models for solvents were used. The first was a continuum model, COSMO (Conductor-like Screening Model), and the second one (based on Monte Carlo simulations) explicitly considers each molecule of the solvent. The results showed that the solvents affected the electron accepton properties allowing the acceptance of two electrons. These aspects have been not been observed before from vacuum calculations and it is of important biological consequence because the melanins can be the base of mechanism of cellular defense against free radicals. The peaks of absorption spectra of the solvated structure are dislocated from red and broadened. This could contribute to the characteristic broad band of eumelanins. Many others important aspects are in better agreement with experimental data when solvent aspects are explicitly taken into account. One of most important results was the observation that solvent effects can alter the order of the lowest energy dimer configuration in relation to the structures in vacuum. This dimer was suggested to be the nucleation seed for the polymer formation. / Mestrado / Física Atômica e Molecular / Mestre em Física

Melanina

Estrutura eletrônica

Solventes

Análise espectral

Métodos semi-empíricos

Melanin

Electronic structure

Solvents

Spectroscopy

Semi-empirical methods

Investigação em eletrônica molecular: um estudo via cálculos de primeiros princípios / Molecular electronics investigation: a first principles study

Renato Borges Pontes

09 November 2007

O iminente fim da \"era do Silício\" tem motivado a busca de novas tecnologias para utilização na indústria eletrônica. Dentre estas tecnologias, a eletrônica molecular explora o uso moléculas como elementos funcionais em dispositivos eletrônicos. Nesta Tese, realizamos cálculos de primeiros princípios baseados na teoria do funcional da densidade (DFT) para determinar as propriedades eletrônicas, estruturais e de transporte em sistemas com aplicação em eletrônica molecular. Para o benzeno-1,4-ditiol (BDT), considerado um sistema protótipo dentro da eletrônica molecular, correlacionamos a adsorção, em uma superfície de Au, com as propriedades de transporte. Na sequência, analisamos evolução estrutural e o efeito de átomos de Au adsorvidos na superfície de Au na transmitância do BDT entre eletrodos de Au. A importância da correção de auto-interação (SIC), nos cálculos de transporte da junção molecular (Au/BDT/Au), também foi discutida. Em seguida, determinamos as propriedades eletrônicas e estruturais da molécula y[(tpy SH)2]x, onde y representa os metais de transição Co, Fe e Ni e; x está associado aos estados de carga 0, +, 2+ e 3+. Verificamos que os metais de transição ficam em uma configuração de baixo spin e, dependendo do estado de carga do metal de transição uma distorção Jahn-Teller leva a uma redução na simetria local de D2d para C2v. Por fim, devido à possibilidade de aplicação em spintrônica, discutimos o efeito de uma impureza de Cobalto na evolução estrutural e transmitância de um nanofio de Au. / The possible end of the road for Silicon has motivated academic researchers and research laboratories to search for new technologies to be applied in the electronic industry. The molecular electronics, which studies the possibility of using molecules as active elements in a new generation of electronic devices, is among these new technologies. In this Thesis, we performed first principles calculations within the density functional theory (DFT) framework to determine the structural, electronic and transport properties of systems with strong application on molecular electronics. We analised the benzene-1,4-dithiol (BDT). For this prototypical system we coupled its adsorption on an Au(111) surface with its transport properties. After this, we investigated its structural evolution between gold leads and the effects of adsorded gold atoms on the Au(111) surface in the trasmitance. The effect of the self-interaction correction (SIC) in the transport calculations of the molecular junction (Au/BDT/Au) was discussed as well. Moreover, we determined the electronic and the structural properties of the molecule y[(tpySH)2]x, where y stands for the transition metals Co, Fe and Ni and; x is associated with the charge states 0, +, 2+ e 3+. We verified that the transition metals are more stable at the low spin configuration. Depending on the charge state a Jahn-Teller distortion leads to a local symmetry reduction: D2d to C2v. Finally, with a spintronic application in mind, we analised the effect of a Cobalt impurity on the structural evolution and transmitance of a gold nanowire.

estrutura eletrônica

simulação computacional

teoria do funcional da densidade

transporte quântico

computational simulation

density functional theory

electronic structure

quantum transport

Estudo de um sistema bidimensional formado por rede de antipontos para a engenharia de dispositivos em spintrônica / Study of a two-dimensional system formed by antidot lattices for engineering of spintronic devices

Julio César Bolaños Pomayna

12 April 2013

Neste trabalho, apresentamos estudos sobre o magnetotransporte em um sistema de bicamadas com uma rede de antipontos triangulares em campos magnéticos baixos sob a aplicação de campos elétricos externos, que são produzidos por voltagens de porta. A bicamada é feita em poços quânticos largos (wide quantum well) de alta densidade eletrônica, formado em heteroestruturas semicondutoras de AlxGa1xAs=GaAs. Oscila- ções magneto-inter-sub-banda (MIS) são observadas em poços quânticos largos de alta densidade eletrônica com duas sub-bandas ocupadas. Estas são originadas pelo espalhamento inter-sub-bandas e tem um máximo para campos magnéticos B que satisfazem a condição de alinhamento entre os leques dos níveis de Landau de cada sub-banda. Oscila- ções de comensurabilidade são observadas na magnetoresistência que é sensível ao arranjo do potencial dos antipontos. A aplicação de campos elétricos faz diminuir o número de oscilações na magnetoresistência para campos magnéticos compreendidos entre 0; 1T e 0; 4T, observando-se uma transição das oscilações MIS aos efeitos de comensurabilidade. Aplicando voltagens de porta podemos variar a amplitude do potencial dos antipontos. / In this work, we present studying about magnetotransport in a bilayer system with triangular antidot lattices in low magnetic elds under the application of external electric eld. The bilayer forms inside a wide quantum well of high electron density in semiconductor heterostructures formed by AlxGa1xAs=GaAs. Magneto-inter-subband (MIS) oscillations are observed in a wide quantum wells of high electron density with two subbands occupied, and they are caused by intersubband scattering and have a maximum for a magnetic eld B that satises the alignment condition between the staircase of Landau level. Commensurability oscillations are observed in magnetoresistance, which is sensitive to the potential of antidot arrangements. The application of electric elds decrease the number of oscillations in the magnetoresistance for magnetic elds between 0; 1T and 0:4T, showing a transition of MIS oscillations to commensurability oscillations. We varied the amplitude of the potential of the antidots applying dierent gate voltages.

Campo magnético

Estrutura eletônica

Poços quânticos

Rede de antipontos

Spintrônica

Antidot lattices

Magnetic field

Quantum well. electronic structure

Spintronic

Estudo da estrutura eletrônica e das propriedades ópticas de copolímeros formados por vinilenos e anéis de tiofeno / Study of electronic structure of the propriety optics of copolymers make for vinylene and rings of tiophene

Marçal, Nei

12 August 2018

Orientador: Bernardo Laks / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Fisica Gleb Wataghin / Made available in DSpace on 2018-08-12T11:04:39Z (GMT). No. of bitstreams: 1 Marcal_Nei_D.pdf: 86929566 bytes, checksum: 04c8aa7c4176175d973ff0990de45bad (MD5) Previous issue date: 2008 / Resumo: Antes da década de 70, todos os materiais poliméricos eram considerados como isolantes e suas aplicações tecnológicas levavam em conta esta característica. De lá para cá, uma nova classe desses materiais, os polímeros conjugados, determinaram uma nova forma de aplicação de sistemas poliméricos baseados em suas propriedades elétricas e de ótica não-linear. Um maior estímulo surgiu a partir do experimento de Mac Diarmid, Heeger e Shirakawa [1] que, expondo o Poliacetileno a agentes oxidantes, demonstraram ser possível obter um sistema no estado metálico. Atualmente encontramos filmes de Poliacetileno com condutividade elétrica da ordem do cobre (105 S/cm). O Poliacetileno, quando no regime metálico, i.e., sob alta dopagem, apresenta algumas características de metal comum: alta condutividade elétrica (cresce 13 ordens de grandeza), susceptibilidade de Pauli finita e absorção no infravermelho. Já outras propriedades como a presença de modos vibracionais localizados no infravermelho e o não comportamento da condutividade com o inverso da temperatura evidenciam ser este um material não usual. Estes polímeros conjugados que apresentam uma extensiva delocalização de elétrons são considerados semicondutores orgânicos com gap de energia relativamente pequeno, da ordem de 1,5 a 2,0 eV. O comportamento semicondutor e as propriedades decorrentes entre os elétrons e a luz têm originado a construção de vários dispositivos semicondutores e optoeletrônicos [2, 7, 3]. Problemas técnicos como estabilidade ao ambiente, processabilidade e solubilidade destes materiais provocaram a produção de uma nova classe de materiais poliméricos que foi obtida por polimerização eletroquímica [57, 58, 59] cuja estrutura molecular trata-se de sistemas que introduzem grupos vinilas (V) entre anéis de tiofeno (T). Experimentos de voltametria cíclica, espectroscopia de absorção ótica e ressonância eletrônica de spin indicam que esses sistemas possuem potencial de ionização e gap de energia menores que o apresentado pelo Politiofeno. Estudos com oligômeros de tiofeno (T) com vinilenos (V) sugerem a possibilidade de escolha desse material como alternativa ao politiofeno. O objetivo deste trabalho foi investigar teoricamente a influência do grupo vinila (V) sobre as propriedades eletrônicas nestes polímeros, reproduzir os resultados experimentais e determinar qual proporção de vinilenos (V) e tiofenos (T) que provoque o menor gap de energia de forma que quando sobre dopagem possibilite uma transição isolante metal. Desta maneira, primeiramente, determinamos as geometrias dos sistemas de interesse utilizando métodos semi-empíricos. Posteriormente investigamos a estrutura eletrônica dos polímeros de tiofeno (T) com vinilenos (V), sendo que estes polímeros foram estudados para o caso neutro e na presença de defeitos conformacionais do tipo pólaron e bipólaron. Finalizamos o estudo investigando as absorções ópticas UV-vis dos sistemas de interesse através de cálculos semi-empíricos utilizando o código ZINDO/S. / Abstract: Before the 1970s, all polymeric materials were considered insulators; therefore their technological applications would take this trait into account. Since then, a new development on these materials, the conjugated polymers, determined new applications for polymeric systems based in their electrical and nonlinear optical properties. Greater interest arose from the experiment by Mac Diarmid, Heeger and Shirakawa [1] who, by using polyacetylene and oxidizing agents, showed that it is possible to obtain a system in the metallic state. Nowadays it is possible to find polyacetylene films with electrical conductivity of the order of copper (10-5 S/cm). Polyacetylene, when in its metallic behavior, i.e., under high dopage, presents some characteristics of real metal: high electrical conductivity (increased by 13 orders of magnitude), finite Pauli susceptibility and infrared absorption. On the other hand, other properties such as the presence of vibrational modes localized on infrared and the odd behavior of conductivity versus the inverse of temperature make clear that this is a unusual material. These conjugated polymers, presenting an extensive delocalization of electrons, are considered organic semiconductors with relatively low energy gap, of the order of 1.5 to 2.0 eV. The semiconductive behavior and the resulting properties of the interaction between electrons and light have been the drive for the manufacturing of several semiconductor and optoelectronic devices [2, 7, 3]. Technical problems, such as environmental stability, processability and solubility of these materials, gave rise to the production of a new kind of polymeric materials that were obtained by electrochemical polymerization [57, 58, 59], in which the molecular structure is a system that introduces vinylene groups (V) between tiophene rings (T). Experiments involving cyclic voltametry, optical absorption spectrometry and spin electronic ressonance indicate that these systems have ionization potential and energy gap smaller than those presented by Polythiophene. Studies with thiopene oligomers (T) with vinylene (V) suggest this material can be chosen as an alternative to Polytiophene. The goal of this work is to theoretically investigate the in uence of the vinyle group (V) on the electronic properties on these polymers, reproduce experimental results and determine what is the vinylene (V) to thiophene (T) rate that causes the smallest energy gap, such that doping will produce a insulator-metal transition. Therefore, we first determine the target systems' geometry using semi-empirical methods. Then we investigate the electronic structure of the tiophene (T) and vinylene (V) polymers both for neutral systems and in the presence of conformational defects of polaron and bipolaron types. We nalized the study by investigating the UV-vis optical absorption of the target systems through semi-empirical calculations using ZINDO/S code. / Doutorado / Estrutura Eletronica de Atomos e Moleculas ; Teoria / Doutor em Ciências

Estrutura eletrônica

Modelos semi-empíricos

Polímeros conjugados

Transições metal-isolante

Electronic structure

Semi-empirical model

Conjugated polymer

Metal-insulator transitions

Viabilidade em programação não-linear : restauração e aplicações / Nonlinear programming feasibility: restoration and applications

Francisco, Juliano de Bem

02 October 2005

Orientador: Jose Mario Martinez / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Matematica, Estatistica e Computação Cientifica / Made available in DSpace on 2018-08-04T03:19:31Z (GMT). No. of bitstreams: 1 Francisco_JulianodeBem_D.pdf: 963435 bytes, checksum: 88cedcb7cfb40d6a63f0ce67f0abb970 (MD5) Previous issue date: 2005 / Resumo: Algoritmos robustos e numericamente viáveis para resolver problemas de otimização têm sido cada vez mais solicitados em problemas práticos que aparecem em engenharia, química, física, entre outras áreas. Com isso em mente, este trabalho apresenta um novo método globalmente convergente baseado em região de confiança para resolver sistemas não-lineares indeterminados (mais incógnitas do que equações) com restrições de caixa, podendo, portanto, ser aproveitado para a fase de viabilidade nos algoritmos baseados em restauração periódica. É mostrado que esse método apresenta, sob certas hipóteses, convergência localmente quadrática. Em uma outra parte deste trabalho é apresentado um novo algoritmo globalmente convergente, o qual se baseia em região de confiança, para resolver problemas de otimização do tipo min f(x); s:a: x 2 D; onde f : Rn ! R é assumida para ser continuamente diferenciável e D C Rn, um subconjunto fechado arbitrário. Em vez de considerar a região de confiança explicitamente nos subproblemas, esse método introduz um parâmetro de regularização que busca imitar a região de confiança. Com essa caracterização, os subproblemas consistem em minimizar um modelo quadratico de f sujeito ao subconjunto D. Uma importante aplicação desse novo algoritmo aparece em química quântica e resultará em um novo algoritmo globalmente convergente, robusto e numericamente viável para calcular estruturas eletrônicas de átomos e moléculas / Abstract: Abstract Robust and numerically feasible algorithms for solving optimization problems have been demanded for solving practice problems that appear in Engineering, Chemistry, Physics and others. This work present a new globally convergent method based on trust regions for solving box-constrained underdetermined nonlinear systems (more unknowns than equations), that can be used on the feasibility fase of algorithms based on periodic restoration. Under some assumptions, it will be proved locally quadratic convergence. In other part of this work, a new globally convergent algorithm is introduced, based on trust regions, for solving the optimization problem min f(x); s:t: x 2 D; where f : Rn ! R is continuously dierentiable and D C Rn is an arbitrary closed subset. Instead of considering explicitly the trust region on the subproblems, the method introduces a regularization parameter that mimics the trust region. With this characterization, the subproblems consist on minimizing a quadratic model of f subject to D. numerically feasible globally convergent algorithm for electronic structure calculations is obtained. / Doutorado / Matematica Aplicada / Doutor em Matemática Aplicada

Otimização matemática

Programação não-linear

Sistemas não-lineares

Estrutura eletrônica

Mathematical optimization

Nonlinear programming

Electronic structure

Nonlinear systems

Magnetic resonance properties of metal-containing nanosystems

Roukala, J. (Juho)

03 October 2016

Abstract This thesis presents computational first-principles investigations of nuclear magnetic resonance (NMR) parameters in metal-containing nanosystems. Special attention is paid to the relativistic effects observed in the vicinity of heavy elements. Small transition metal complexes are used to assess the feasibility of a quasirelativistic density functional theory (DFT) approach for calculating nuclear magnetic shielding tensors of increasingly heavy metal nuclei, followed by applications of the concept to larger systems. Nuclear magnetic shielding constants, shielding anisotropies, and chemical shifts with respect to metal ions are calculated in dimethyl and water complexes of the group-12 transition metals 67Zn, 111/113Cd, and 199/201Hg, using Hartree–Fock and DFT methods with relativistic corrections from the Breit–Pauli Perturbation Theory (BPPT). Four-component relativistic Dirac–Hartree–Fock and correlated, nonrelativistic ab initio calculations are used to benchmark the BPPT and DFT methods, respectively. The DFT/BPPT approach, combined with Monte Carlo simulations at finite temperatures, is subsequently used to calculate the chemical shift of a guest 129Xe inside a tetrahedral, iron-based cage. Complementing experiments, the encapsulation of xenon is verified, and empirically elusive details are revealed about the guest dynamics. Finally, the full shielding tensors of 31P and 195Pt and the indirect spin–spin coupling constants between the two nuclei are studied in five crystalline platinum(II) dialkyldithiophosphato complexes, concentrating on the solid-state chemical shift anisotropy and asymmetry parameters of phosphorus and platinum. The NMR parameters are calculated using DFT and the two-component zerothorder regular approximation (ZORA) for relativistic effects, combining molecular and solid-state models to incorporate indispensable contributions due to spin–orbit and crystal lattice corrections for the shielding tensors. Four-component matrix-Dirac–Kohn–Sham shielding calculations are used to benchmark the ZORA method. Qualitative, in cases nearly quantitative agreement is obtained with experiments, allowing the validation of the X-ray structures of the complexes, as well as a deeper analysis of the differences between them, including the major contributions to the NMR parameters. The results presented here demonstrate that computational NMR, a branch of relativistic quantum chemistry, is applicable and useful in studying nanoscale systems containing heavy elements, such as transition metals. Approximations are necessary to enable the treatment of large and complex targets, but sufficient accuracy is achieved for supplementing experiments with reliable and useful data that provides additional insight and analysis possibilities.

Monte Carlo simulation

density functional theory

electronic structure

magnetic resonance parameters

nuclear magnetic resonance spectroscopy

special relativity

Static and dynamic NMR properties of gas-phase xenon

Hanni, M. (Matti)

28 May 2011

Abstract This thesis presents computational studies of both the static and dynamic parameters of the nuclear magnetic resonance (NMR) spectroscopy of gaseous xenon. First, state-of-the-art static magnetic resonance parameters are computed in small xenon clusters by using methods of quantum chemistry, and second, time-dependent relaxation phenomena are investigated via molecular dynamics simulations at different experimental conditions. Based on the underlying quantum and classical mechanics concepts, computational methods represent a procedure complementary to experiments for investigating the properties of atoms, molecules, clusters and solids. Static NMR spectral parameters, chemical shift, shielding anisotropy and asymmetry parameter, nuclear quadrupole coupling, and spin-rotation coupling, are calculated using different electronic structure methods ranging from the uncorrelated Hartree-Fock method to correlated second-order Møller-Plesset many-body perturbation, complete/restricted active space multiconfiguration self-consistent field, and to coupled-cluster approaches. The bond length dependence of these properties is investigated in the xenon dimer (Xe2). A well-characterized property in experimental NMR, the second virial coefficient of nuclear shielding, is theoretically calculated by a variety of methods and convincingly verified against experimental findings. Here, it is mandatory to include effects from special relativity as well as electron correlation. As a side result, a purely theoretical potential energy curve for Xe2, comparable to best experimental ones, is calculated. A pairwise additive scheme is established to approximate the NMR properties in differently coordinated sites of xenon clusters Xen (n = 2 - 12). Especially the pairwise additive chemical shift values are found to be in close agreement with quantum-chemical results and only a small scaling factor close to unity is needed for the correct behavior. Finally, a dynamical magnetic resonance property, the experimental nuclear spin-lattice relaxation rate R1 of monoatomic Xe gas due to the chemical shift anisotropy (CSA) mechanism is validated from first principles. This approach is based on molecular dynamics simulations over a large range of temperatures and densities, combined with the pairwise additive approximation for the shielding tensor. Therein, the shielding time correlation function is seen to reflect the characteristic time scales related to both interatomic collisions and cluster formation. For the first time, the physics of gaseous xenon is detailed in full in the context of CSA relaxation.

chemical shift anisotropy relaxation

electronic structure

molecular dynamics

nuclear magnetic resonance spectroscopy

pairwise additivity

potential energy curves

spectral parameters

xenon

Supramolecular organisation, conformation and electronic properties of porphyrin molecules on metal substrates

Weber, Alexander

05 1900

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

Chemistry and physics of diamond surfaces

Domke, Andreas

January 1999

This thesis is concerned with the chemistry and physics of C(100) surfaces of diamond. The polished and cleaned C(100) surface is examined by surface microscopy (Atomic-force Microscopy), electron diffraction (Low-energy Electron Diffraction) and photoemission (X-ray Photoelectron Spectroscopy and Ultra-violet Photoelectron Spectroscopy). Results are presented on the presence of oxygen, nitrogen and hydrogen/deuterium on the C(100) surface. Finally, the valence band structure of diamond is probed by angle-resolved photoemission. We have confirmed by AFM that the grooves from the soft polishing process are present on a polished C(100) surface and found sporadic traces of hard polish on a surface polished in the soft polishing direction. XPS studies have verified heating cycles by electron beam bombardment as a suitable cleaning procedure for pure reconstructed C(100) surfaces. By allowing the crystal to cool slowly, the first experimental evidence of quarter-order LEED spots have been found, which suggest that buckled dimerisation might have occurred similar to those on Si(100) and Ge(100). We present the first experimental electron spectroscopy results for a nitrogen impurity in diamond by showing the N KLL Auger spectrum. An attempt to smooth a C(100) surface of diamond by an atomic hydrogen plasma did not succeed. AFM studies showed no evidence for the surface smoothing reported in other studies, but the results enable us to explain the different plasma published in the literature. The valence band of diamond is investigated by off-normal ARUPS. The features observed are consistent with possible transitions, which are determined using bulk band structure calculations and comparison with the experimental binding energies.

541

Studies On Electronic Properties Of Amorphous Conducting Carbon Films

Bhattacharyya, Somnath

12 1900

No description available.

Carbon - Electronic Properties

Carbon - Electronic Structure

Carbon Films

Amorphous Carbon

Amorphous Carbon Films

Conducting Films

Nanostructured Carbon

Solis State Physics