Creation of defects and interactions between defects and small molecules on TiO���(110) surfaces : comparative SHG and XPG studies

Shultz, Ashley Nicholle

26 April 1996

Graduation date: 1996

Titanium dioxide -- Surfaces

Growth, structure, and chemistry of 1B metal nanoclusters supported on TiO₂(110)

Pillay, Devina

28 August 2008

Not available / text

Titanium dioxide--Surfaces

Copper

Silver

Gold

Surface chemistry

Reactivity (Chemistry)

Second harmonic generation study of photodynamics and adsorption/desorption on rutile TiO surfaces

Jang, Winyann

08 August 1994

Graduation date: 1995

Second harmonic generation

Structure determinations of SnO₂ and TiO₂ surfaces by low energy electron diffraction Patterson inversion method

Leung, Wai-yan., 梁偉恩.

January 2013

The Tin dioxide (SnO2) and Titanium dioxide (TiO2) are very promising materials in Material science. The SnO2 is commonly used as a gas sensor while the TiO2 is used as a catalyst in many reactions. Despite of the usefulness of these two substances, their surface structures lack detail investigations in the previous years. The Low Energy Electron Diffraction (LEED) technique is commonly used to characterize surfaces in the past 40 years, it is a mature system that many researches rely on its result. However, structural analysis in LEED requires comparison with computational results based on pre-defined structure models, which is a time-consuming method and the results are not guaranteed to be found. The direct determinations of structure by Patterson function inversion methods introduced by Huasheng Wu and S. Y. Tong could provide a different path to search for surface structure. In the Patterson function, each maximum in the function corresponds to a relative position vector of atomic pairs. Multiple-angle-incident LEED has to be performed to obtain an artifact-free Patterson function. Serveal SnO2 and TiO2 surfaces have been characterized by LEED and Patterson function inversion. SnO2 (110), (100), (101) , Rutile TiO2 (110), Anatase TiO2 (110) have been prepared by argon ion sputtering and annealing cycles and the cleanness has been checked by Auger Electron Spectroscopy and LEED. Reconstruction is observed based on the study of the LEED patterns. SnO2 (110) surface shows a 4 x 1 reconstruction in UHV environment while it gives 1 x 1 under annealing in oxygen and C(2 x 2) at higher annealing temperature afterward. SnO2 (100) , (101) and Rutile TiO2 (110) surfaces show 1 x 1 reconstruction in UHV environment and the reconstruction persists for further annealing. The Anatase TiO2 (110) surface shows a 3 x 4 reconstruction in UHV environment. The 3 x 4 reconstruction of Anatase TiO2 (110) surface would raise research interests as it is quite a special reconstruction. Multiple-angle-incident LEED has been performed on the SnO2 (100), (101) and Rutile TiO2 (110) surfaces. Patterson function inversion is performed on the surfaces SnO2 (100) and Rutile TiO2 (110) . Only LEED is performed on SnO2 (110) , (101) and Anatase TiO2 (110) surfaces. From Patterson functions analysis, the surface atoms positions are determined for the surface SnO2 (100) and Rutile TiO2 (110). The results show that their reconstructions are negligible, but they have obvious relaxations. / published_or_final_version / Physics / Master / Master of Philosophy

Low energy electron diffraction.

Patterson function.

Stannic oxide - Surfaces.

Titanium dioxide - Surfaces.

Surface modification of titanium dioxide and synthesis of non- electroactive coatings by electrochemical polymerization

Vithanage, Rathnapala S.

January 1985

The objective of this project was the modification of TiO₂ electrodes with various <u>silanes</u> in order to evaluate the stability of modified layers when they are used on <u>photoelectrodes</u> in SEMICONDUCTOR LIQUID-JUNCTION SOLAR CELLS (SLJSC). To determine the nature of the reactivity of surface hydroxyl groups towards different <u>silanes</u>, a surface IR study was carried out on TiO₂ powders. The powder (TiO₂) was pressed into a pellet and subjected to reactions with various silanes under different reaction conditions. All of these reactions were carried out in a <u>vacuum line</u> under very anhydrous conditions in order to prevent polymerization of the silanes. This study provided an understanding of the reactivity of different silanes towards surface hydroxyl groups of TiO₂ and the best reaction conditions for this purpose. With this information in hand we studied the TiO₂ (rutile) <u>single crystal</u> electrodes. These electrodes were subjected to reaction with silanes under the same conditions as the powders. Then the modified surface was studied using ESCA. These electrodes were subsequently subjected to photoelectrochemical conditions (photocurrent generation) and were reexamined using ESCA in order to evaluate the stability of the modified layer. A reaction scheme which was devised to induce crosslinking in the modified layer was shown to enhance the stability of the surface bound silane during the photocurrent generation. In order to form more homogeneous modified surfaces electrochemically derived polymer coatings were synthesized from divinylbenzene, 4-vinylpyridine, N-methyl-4-vinylpyridinium salts, and phenol. Except for polymers formed from N-methyl-4-vinyl pyridinium salts, other coatings were shown to be neutral. An anomalous pre-wave, and potential-induced polymer swelling and shrinking phenomena were observed in these coatings. The photocorrosion of small bandgap n-type semiconductor electrodes is a serious impediment to the development of efficient and durable conversion (photoelectrochemical) devices. Our objective in this investigation was to develop newer modified surfaces that are useful for the inhibition of this photocorrosion, and enhance the performance of n-type small bandgap semiconductors in the photoelectrochemical systems. / Ph. D. / incomplete_metadata

LD5655.V856 1985.V573

Titanium dioxide -- Reactivity

Electrochemistry

Polymers

Titanium dioxide -- Surfaces

Enzymatisch aktivierbare Biokonjugate als oberflächenspezifische Adhäsive

Meißler, Maria

15 March 2018

In der vorliegenden Arbeit wurde gezeigt, dass enzymresponsive Peptid-Poly(ethylenglycol)-Konjugate (Peptid-PEG-Konjugate) effizient biotransformiert und proteinresistente Beschichtungen ausbilden können. Die oberflächenspezifische Haftung eines linearen Biokonjugates auf Basis einer literaturbekannten Adhäsionsdomäne für Titandioxid-Oberflächen wurde durch Verlängerung mit einer proteolytisch spaltbaren Erkennungssequenz und einer Suppressionsdomäne temporär unterbunden. Aus einer Serie unterschiedlich modifizierter Biokonjugate wurde eine anionische Suppressionsdomäne als besonders leistungsfähige haftungsunterdrückende Einheit identifiziert. Die Prozessierung des nicht-bindenden Vorläufers mit einer spezifischen Cysteinprotease hervorgehend aus dem Tabakätzvirus (TEV Protease) bewirkte die Abtrennung der eingeführten Modifikation. Durch die Biotransformation wurden die Haftungseigenschaften der polymergebundenen Adhäsionsdomäne zurückgebildet. Das aktivierte Biokonjugat ermöglichte die nicht-kovalente PEGylierung der Metalloxid-Oberfläche. Das Konzept wurde auf divalente Peptid-PEG-Konjugate unter Verwendung verzweigter Adhäsionsdomänen und verlängerter Suppressionsdomänen übertragen. Die proteolytisch aktivierte Dimer-Beschichtung zeigte eine erhöhte Stabilität im Vergleich zum linearen Biokonjugat und demonstrierte vielversprechende Antifouling-Eigenschaften gegenüber der unspezifischen Adsorption eines Modellproteins für Serumproteine des menschlichen Blutes auf Titandioxid-Oberflächen. / The present thesis has shown that enzyme-responsive peptide-poly(ethylene glycol) (peptide-PEG) conjugates can be efficiently biotransformed to create protein-resistant coatings. The surface-specific adsorption of a linear bioconjugate is temporarily suppressed by extending a titanium dioxide adhesion domain known from literature with a proteolytically cleavable recognition site and a suitable interfering domain. From a series of differently modified bioconjugates, an anionic interfering domain was identified as particularly effective to suppress adhesive functions. The enzymatic processing of the non-binding precursor with a specific cysteine protease derived from tobacco etch virus (TEV protease) resulted in the separation of the introduced modification. The adhesive properties of the polymer-bound binding sequence were reproduced by the biotransformation process. The activated bioconjugate allowed the non-covalent PEGylation of the metal oxide surface. The concept was applied to divalent peptide-PEG conjugates using branched adhesion domains and extended interfering domains. The proteolytically activated dimer coating showed increased stability against dilution compared to the linear bioconjugate and demonstrated promising antifouling properties against the non-specific adsorption of a model protein for human blood serum proteins to titanium dioxide surfaces.

stimuliresponsive Biokonjugate

enzymatische Aktivierung

Adhäsionsdomänen

PEGylierung von Oberflächen

Antifouling-Beschichtungen

Titandioxid-Oberflächen

stimuli-responsive bioconjugates

enzymatic activation

adhesive domains

surface PEGylation

antifouling coatings

titanium dioxide surfaces

547 Organische Chemie

adhesive domains

VX 5657

WD 5050

ddc:547