A structural study of the Si(001) using high resolution helium atom diffraction

Rohlfing, David Michael

January 1987

No description available.

530.41

Silicon surface analysis

Strained silicon/silicon germanium heterojunction n-chanel metal oxide semiconductor field effect transistors

Olsen, Sarah H.

January 2002

No description available.

621

Strained silicon surface channel

Chemical and physical understanding of diffusion barrier layers on semiconductors: (hfac)copper(VTMS) and its ligands on silicon(100)-2 x 1 and titanium carbon nitride-covered silicon

Pirolli, Laurent.

January 2006

Thesis (Ph. D.)--University of Delaware, 2006. / Principal faculty advisor: Andrew V. Teplyakov, Dept. of Chemistry & Biochemistry and Raul F. Lobo, Dept. of Chemical Engineering. Includes bibliographical references.

Study of silver deposition on silicon (100) by IR spectroscopy and patina formation study of oxygen reduction reaction on ruthenium or platinum

Yang, Fan. Chyan, Oliver Ming-Ren,

January 2009

Thesis (M.S.)--University of North Texas, Aug., 2009. / Title from title page display. Includes bibliographical references.

Study of semiconductor and metal surfaces using a novel scanning Kelvin probe

Petermann, Uwe

January 2000

No description available.

530.41

Synthesis and Characterization of Novel Polymers for Functional and Stimuli Responsive Silicon Surfaces

Viswanathan, Kalpana

28 April 2006

The synthesis of a variety of novel functionalized polymers using living polymerization techniques to achieve functional and stimuli responsive coatings on silica surfaces are described. Since microscopic features on a surface influence the overall wetting properties of the surface, a systematic investigation of the influence of polymer architecture on the microscopic characteristics of the modified surfaces was studied using silane-functionalized linear and novel star-branched polystyrene (PS). Star-branched modifiers provide functional and relatively well-defined model systems for probing surface properties compared to ill-defined highly branched systems and synthetically challenging dendrimers. Using these simple star-shaped macromolecules it was shown that the topographies of the polymer-modified surfaces were indeed influenced by the polymer architecture. A model explaining the observed surface features was proposed. A living polymerization strategy was also used to synthesize centrally functionalized amphiphilic triblock copolymers. The amphiphilic copolymers exhibited stimuli responsive changes in surface hydrophobicity. In spite of multiple solvent exposures, the copolymer films remained stable on the surface indicating that the observed changes in surface properties were due to selective solvent induced reversible rearrangement of the copolymer blocks. The chemical composition of the copolymers was tailored in order to tune the response time of the surface anchored polymer chains. Thus, the polymer coatings were used to reversibly change the surface polarities in an on-demand fashion and could find possible applications as smart adhesives, sensors and reusable membrane devices. In contrast to the afore-mentioned covalent modification approach, which often leads to permanent modification of surfaces, renewable surfaces exhibiting "universal" adhesion properties were also obtained through non-covalent modification. By employing hydrogen bonding interactions between DNA bases, surfaces functionalized with adenine groups were found to reversibly associate with thymine-functionalized polymers. This study describing the solvato-reversible polymer coating was the first demonstration on silica surfaces. A systematic investigation of the influence of surface concentration of the multiple hydrogen bonding groups and their structure on the extent of polymer recognition by the modified surfaces is also discussed. / Ph. D.

star-branched polymers

Silicon surface modification

amphiphilic block copolymers

multiple hydrogen bonding

responsive surfaces

Fonctionnalisation de surfaces de silicium hydrogéné par des tétrathiafulvalènes et des complexes dithiolène / Functionalization of hydrogen-terminated silicon surfaces by tetrathiafulvalene and dithiolene complexes

Yzambart, Gilles

18 December 2013

La fonctionnalisation de surfaces de silicium hydrogéné par des films de molécules organiques suscite un intérêt croissant en raison des nombreuses applications potentielles (photovoltaïsme, détection chimique et biochimique, électronique moléculaire...). Dans ce cadre, nous avons cherché à greffer des tétrathiafulvalènes ou des complexes dithiolène de platine à ligand bipyridine, électroactifs, sur cette surface par hydrosilylation d’alcynes. Nous avons montré que ces composés organiques étaient bien immobilisés par une liaison robuste Si-C et nous avons noté la présence de plusieurs états redox stables et réversibles associés aux molécules greffées. Les méthodes de greffage direct et de post-fonctionnalisation de monocouches, ont permis l’obtention de films denses stables aux constantes de transfert de charge élevées. / The functionalization of silicon surfaces by thin layers of organic molecules raises increasing interest due to the large extent of potential applications (photovoltaics, chemical and biochemical detection, molecular electronics and so on). In this context, we have prepared TTF and platinum dithiolene complex-modified silicon surfaces through a hydrosilylation reaction between hydrogen-terminated silicon and alkyne-terminated precursors. We have shown that these organic compounds were covalently bound to the surface through a robust Si-C bond. We have demonstrated that the electroactivity of the grafted molecules characterized by several reversible one-electron systems was maintained after the immobilization step. Post-functionalization and direct grafting reactions lead to dense and stable films, with high values of electron-transfer rate constants.

Surface de silicium

Monocouche organique

Ligands dithiolène et bipyridine

Tétrathiafulvalène

Fonctionnalisation

Silicon surface

Organic monolayer

Dithiolene and bipyridinium ligands

Tetrathiafulvalene

Functionalization

Characterization, Functionalization and Applications of Alkyl Monolayers on Silicon Surfaces

Jiang, Guilin

02 February 2006

Investigations were performed on the stability, mechanism of formation and an application of alkyl monolayers chemomechanically prepared on silicon surfaces. A new method of surface modification, laser-activation modification of surfaces (LAMS), and multivariate analyses of time-of-flight secondary ion mass spectrometry (ToF-SIMS) images of LAMS spots were also reported. X-ray photoelectron spectroscopy (XPS) and other data show that alkyl monolayers prepared by scribing silicon under 1-iodoalkanes and 1-alkenes were stable over extended periods of time to air, water, a boiling acid and Al Ka X-rays. The stability is attributed to direct Si-C bonding in the monolayers. The observation that the oxygen signals gradually increased and the iodine signals gradually decreased, with both finally reaching plateaus is attributed to the oxidation of exposed silicon by scribing, and the hydrolysis of Si-I bonds, respectively. In alkyl monolayers prepared with 1-alcohols, the carbon signals decreased about 50% after two 1-h immersions in a boiling acid, suggesting unstable Si-O bonding. In the analogous experiment of grinding silicon with alkyl halides, the expected free-radical combination and disproportionation byproducts were observed. This observation provides evidence for the mechanism previously proposed for alkyl monolayer formation on silicon by chemomechanically scribing. Miniaturized sample supports for matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) were made on hydrophobic silicon or glass surfaces by scribing. With these sample supports, improved MALDI-MS signal intensities and reproducibilities were achieved for a test peptide, as expected. A new and promising method for surface modification, LAMS, was developed. XPS and ToF-SIMS analyses show that both silicon and germanium were effectively modified by LAMS with even quite inert compounds. This technique was also used to make miniaturized MALDI-MS sample supports. Compared to scribing, LAMS is faster and can be more precisely controlled. Multivariate analyses, automated expert spectral image analysis (AXSIA) and principal component analysis (PCA), were used in interpreting ToF-SIMS images of silicon surfaces modified with 1-alkenes by LAMS. Both analyses show that modified and unmodified areas are chemically different.

Alkyl monolayers

Silicon surface modification

ToF-SIMS Imaging

Multivariate analysis

Biochemistry

Chemistry

Durability and Adhesion of a Model Epoxy Adhesive Bonded to Modified Silicon Substrates

Xu, Dingying

07 July 2004

The adhesion and durability of model epoxy/silane/SiO2/Si bonded systems were investigated under various conditions, including the type of surface preparation, pH of the environmental media, temperature, cyclic thermal stress, and external applied stress. The fundamental debond mechanism was studied for bonded systems exposed to selected environments. The bond failure mode was characterized by examining the failed bond surfaces using X-ray photoelectron spectroscopy. The effectiveness of combining the oxygen plasma treatment and silane coupling agent (SCA) derivatization in adhesion promotion for an epoxy bonded to a silicon surface was evaluated in this research. SCAs with different amine functionalities were studied. The oxygen plasma treatment time was varied systematically to achieve a different extent of oxidation on the Si wafer. The surface chemistry/composition of various silane derivatized Si surfaces was investigated. The studies revealed that SCA interaction with the Si surface was enhanced by the oxygen plasma pre-treatment of the Si substrates. XPS surface analysis results showed that the SCA/SiO2 ratio did not correlate strongly with the increase in oxygen plasma pretreatment time. However, for Si surfaces treated for longer oxygen plasma pretreatment times, more silanol groups may be available to interact with the hydrolyzed silanol groups on silane, resulting in a stronger SCA-Si attachment. Three different tests were employed to determine adhesion and durability of the model epoxy/SCA/SiO2/Si bonded specimens. The immersion test qualitatively evaluates the bond durability for various systems exposed to different chemical and thermal conditions. Second, a novel probe test was used to quantitatively determine adhesion under critical debonding conditions for bonded specimens with different SCA preparations. A general trend of bond durability varied in the manner SCA-2 > SCA-3 > SCA-1 > no silane. Bond durability also increased for samples: model epoxy/SCA modified/O2 plasma treated/Si as the oxygen plasma pre-treatment time increased. Third, bond durability was studied using the wedge DCB (double cantilever beam) test under subcritical debonding conditions with environment-assisted crack growth as a function of applied strain energy release rate. Higher crack velocity and the absence of a Gthreshold value were noted in tests at 70 oC. The Gthreshold value increased as the strength of the interface increased and as the chemical aggressiveness of the environment decreased. For tests involving 25 oC -70 oC thermal cycling, only limited crack growth was found. / Ph. D.

probe test

silane coupling agent

durability

failure analysis

silicon surface modification

plasma treatment

adhesion

epoxy

X-ray photoelectron spectroscopy

De la molécule unique au tapis supramoléculaire sur surface de silicium passivée : Simulations numériques à l'échelle atomique / From the single molecule to supramolecular network on passivated silicon surface : Numerical simulations at the atomic scale

Boukari, Khaoula

20 September 2013

Ma thèse porte sur l’étude par simulations numériques à l’échelle atomique de l’adsorption de molécules uniques et d’auto-assemblages moléculaires sur la surface de silicium Si(111) dopée bore notée Si(111) (√(3 ) x√3)R30°-B. Après un premier chapitre de présentation des méthodes de calcul, puis un chapitre consacré à la surface Si(111)-B, la thèse se divise en deux grandes parties : l’une concernant l’adsorption de molécules uniques et l’autre consacrée à l’adsorption de tapis moléculaire.La première partie concerne l’adsorption de molécules uniques sur la surface de Si(111) (√(3 ) x√3)R30°-B. Nous avons plus particulièrement étudié trois molécules présentant des mécanismes d’adsorption différents : la molécule de pyridile-azobenzène, une molécule de la famille des porphyrines (Cu-TBPP) et deux molécules appartenant à la famille des phtalocyanines (H2Pc et CuPc). Dans chaque étude, nous avons effectué une étude énergétique, structurale et électronique. Dans la plupart des cas, nous avons complété l’étude par un calcul d’image STM pour comparer avec les résultats expérimentaux. A partir de cette étude, nous avons montré que les molécules interagissent différemment avec la surface via des interactions électrostatiques, des liaisons datives, des liaisons ioniques et un mécanisme de cycloaddition. La deuxième partie de la thèse est dédiée à l’étude de l’auto-assemblage de molécules organiques sur la surface Si(111) (√(3 ) x√3)R30°-B. L’auto-assemblage moléculaire est une technique permettant la fabrication d’architectures hautement organisées à l’échelle atomique. Nous avons étudié trois molécules différentes formant un auto-assemblage sur la surface de Si(111)-B : 1,3,5-tri(4-bromophényle benzène) notée TBB, 1,3,5-tri(4-iodophényle benzène) notée TIB et 1,3,5-triphenylbenzene notée THB. Comme la formation d’un réseau auto-organisé est la conséquence d’un équilibre entre les interactions molécule-molécule et molécules-substrat, nous avons évalué les énergies d’interaction mises en jeu en utilisant différentes approximations (LDA, GGA et GGA+D). Nous avons étudié, ensuite, les propriétés électroniques de ces assemblages par le calcul des densités d’états projetées, de la différence de la densité de charge, du Laplacien de la charge ou de la fonction ELF. Afin de comparer nos résultats avec les résultats expérimentaux, nous avons effectué un calcul d’image STM en utilisant deux approches : l’approche de Tersoff-Hamann et l’approche multidiffusion proposée par le code bSKAN. Dans une dernière étape, nous avons étudié la recroissance de molécules de fullerène C60 sur le réseau auto-organisé de molécules de TBB déposées sur la surface Si(111) (√(3 ) x√3)R30° -B. Nous avons effectué une étude énergétique des molécules de C60 qui se déposent préférentiellement dans les nanopores de forme hexagonale en accord avec les expériences STM. / My thesis presents the study of the adsorption of single molecules and molecular self-assembly, by numerical simulations at the atomic scale, on a boron doped silicon surface denoted Si(111)(√(3 ) x√3)R30°-B. After presenting the calculation methods and describing the surface model, this thesis is made of two parts: the first one is about the adsorption of single molecules and the second one is devoted to the formation of supramolecular network. In the first part, I studied the adsorption of single molecules on the silicon surface doped boron Si (111)(√(3 ) x√3)R30°-B. I have investigated the adsorption mechanisms of three different molecules: a molecule of pyridyl-azobenzene, a molecule of the family of porphyrin (Cu-TBBP) and two molecules which belong to the family of phtalocyanine (H2Pc and CuPc). For every molecule, I conducted energetic, structural and electronic studies. In most of the cases, I completed this work by calculating STM images in order to compare with experimental results. The second part of this thesis deals with the study of self assembly of organic molecules on the surface of Si(111)(√(3 ) x√3)R30°-B. Molecular self assembly is a technique which allows the formation of highly organized architectures at the atomic scale. I have studied three different molecules forming self assembly on the surface of Si (111)(√(3 ) x√3)R30°-B : 1,3,5-tri(4-bromophenyl benzene) denoted TBB, 1,3,5-tri(4-iodophenyle benzene) denoted TIB et 1,3,5-triphenylbenzene denoted THB. As the formation of a self organized network is a result of equilibrium between molecule-molecule interaction and molecule-substrate one, I have evaluated the interaction energies by using different approximations (LDA, GGA and GGA+D). Then, I have studied the electronic properties of these assemblies by calculating the projected density of states, the charge difference and the Laplacien of the charge or the ELF function (Electronic Localization Function). In order to compare our results with experimental ones, STM images calculations were performed by using two different approaches: the approach of Tersoff-Hamann and the multi-scattering approach proposed by bSKAN code. Finally, I have studied the growth of C60 molecules on the self organized network formed by the TBB molecules deposited on the Si (111)(√(3 ) x√3)R30°-B surface. The energetic study shows that C60 molecules are adsorbed preferentially in the hexagonal nanopores in agreement with the STM observations.

Simulation

Surface de silicium

Adsorption

Molécule organique

Tapis moléculaire

STM

Recroissance

DFT

Simulation

Silicon surface

Adsorption

Organic molecule

Molecular network

Regrowth

530