Challenges and errors: interpreting high resolution images in scanning tunneling microscopy

With the availability of first principles methods to simulate the operation of a scanning tunneling microscope (STM) theory has moved from the qualitative and topographic to the quantitative and dynamic. Simulations in effect predict the influence of a model-tip or chemical interactions between tip and sample in the actual imaging process. By comparing experiments and simulations, the information about the analyzed system can be substantially extended. We give an overview of recent work, where the combination of first principles simulations with high resolution measurements was decisive to arrive at consistent results. This concerns the resolution of single wavefunctions by STM, force effects in high resolution scans, contrast reversal due to the field of the tip, the imaging of magnetic properties by spin-polarized STM, and the analysis of dynamic processes on surfaces.     

In situ second harmonic generation studies from covered Ag(111) electrodes

The second harmonic response of Ag(111) electrodes has been studied in the presence of adsorbates. Two different kind of systems have been investigated: films of biphenyl derivatives and halide adsorbates. The presence of the adsorbates is shown to affect markedly the isotropic response of the interface, while the anisotropic part seems to be generated solely by the metal.Dedicated to Prof. Wolf Vielstich on the occasion of his 80^th birthday in recognition of his numerous contributions to interfacial electrochemistry     

研究甲酸在多孔Pt上吸附质的性质以及它与CO的相互作用

应用现场红外反射光谱和微分电化学质谱研究了甲到在多孔Ｐｔ上吸附质的性质。伏安结果显示了甲酸在多孔Ｐｔ上吸附质的氧经与吸附电位和吸附时间有关。在线质谱结果表明从甲酸吸附质氧化成二氧化碳所需要的电子数（ｎｅ）与吸附电位无关。显著地ｎｅ＝２．２说明了甲酸吸附质是由ＣＯ和ＣＯＨ组成，而不是只有单一的ＣＯ或者ＣＯＨ，另一方面，在１２６２ｃｍ＾－１和２０４８ｃｍ＾－１出现的现场红外光谱带证实了甲酸在多孔Ｐｔ上     

NEXAFS microscopy studies of the association of hydrocarbon thin films with fine clay particles

The nature of organic species associated with clay minerals plays a significant role in several processes, from hydrocarbon recovery in oil sands to contaminated soil remediation and water treatment. In this work, we address the use of scanning transmission X-ray microscopy (STXM) in conjunction with near edge X-ray absorption fine structure (NEXAFS) spectroscopy to study the microstructure and chemistry of organic–clay associations in situ. A model system based on methylene blue and illite is used to explore the sensitivity of NEXAFS microscopy to these interactions, and to identify and resolve experimental challenges in these measurements. We find that sample contamination from X-ray induced photodeposition is a significant problem in STXM microscopy, but also that this problem can be substantially reduced with a liquid nitrogen cooled anticontaminator. With appropriate sample preparation and experimental procedures, we find that STXM microscopy is sensitive to thin carbon adsorbates on clay surfaces.     

Surface potentials of few-layer graphene films in high vacuum and ambient conditions

The surface potentials of few-layer graphene (FLG) films in high vacuum and ambient conditions have been investigated by employing electrostatic force microscopy. It is found that the surface potential of FLG films in ambient air has a constant large depression compared to that measured in a high vacuum. Our experimental results indicate that the shift is most likely caused by the presence of ambient adsorbates on the outmost graphene surfaces. The surface potentials increase with the number of graphene layers and approach the bulk value for five or more graphene layers in high vacuum as well as in ambient air. Since the contribution of the surface adsorbates is a constant value, we further show that the thickness dependence of the surface potential can be sufficiently explained by the nonlinear Thomas-Fermi Theory in both conditions.     

First-principles investigation of the electronic properties of niobium and molybdenum mononitride surfaces

Using first-principles calculations we investigated the electronic properties of niobium and molybdenum mononitride (NbN and MoN, respectively) surfaces and their dependence on the surface orientation and termination. Work functions calculated for polar surfaces strongly depend on the surface termination, with nitrogen-terminated surfaces yielding the highest value, up to 6.6 eV for the fully N-covered MoN(0 0 1) surface. The dependence of the work function on coverage for the polar surface is monotonic for nitrogen termination, but does not follow the same trend in the case of metal termination. The work function decreases by ∼2 eV for MoN from a 100% metal-terminated surface to at least 25% metal-terminated surface, and then increases rapidly between 25% and 0% metal-terminated surface to recover its nitrogen termination result. The same trend was obtained for NbN. We observed a significant increase in the charge of the surface metal atom, up to its bulk value, with decreasing metal surface coverage. Electron transfer from the metal surface atoms to the subsurface atoms can explain these submonolayer metal coverage results. Finally we found that for the non-polar surfaces, the mononitrides work functions are generally lower than the work functions of the corresponding simple metal surfaces.     

Hybrid system of iron porphyrin on aminosilanized c-Si

Adsorption of iron porphyrin (Fe^IIITPPS₄) Fe(III)meso-tetra(4-sulfonatophenyl) porphine on aminosilanized surface of crystalline Si (c-Si) was investigated. Formation of nanometric structures of Fe^IIITPPS₄ on c-Si, the surface of which has been modified by various silanization procedures, was studied. Aqueous, ethanol and acetone solutions of 3-aminopropyltrietoxysilane (APTES) were prepared for deposition on c-Si by spinning or immersion techniques. Smooth homogeneous APTES films of thickness 100–500 nm were produced by multiple spin coating procedure. Thin APTES films of thickness 2.5 nm were fabricated by dipping technique followed by washing procedure. Hybrid system of Fe^IIITPPS₄/APTES/Si was prepared from a drop of Fe^IIITPPS₄ aqueous solution put on aminosilanized Si surface or by dipping the Si wafer in Fe^IIITPPS₄ aqueous solution. Nanostructures of size 50–250 nm were formed along with large rings of Ø50–100 μm which have been observed at chemisorption of highly concentrated (1 mM) Fe^IIITPPS₄ aqueous solution. Spectroscopic ellipsometry was used to characterize the APTES layer and to investigate the aggregation state of Fe^IIITPPS₄. The studies provided allowed one to presume that covalent bonds were formed between amino-groups of APTES and functional groups of sulfonic acid in porphyrin leading to immobilization of Fe^IIITPPS₄ on Si substrate.     

Geometric and Electronic Structures of Pyrazine Molecule Chemisorbed on Si(100) Surface by XPS and NEXAFS Spectroscopy

The geometric and electronic structures of several possible adsorption configurations of the pyrazine ({C\begin{document}$ _{4} $\end{document}}{H\begin{document}$ _{4} $\end{document}}{N\begin{document}$ _{2} $\end{document}}) molecule covalently attached to Si(100) surface, which is of vital importance in fabricating functional nano-devices, have been investigated using X-ray spectroscopies. The Carbon K-shell (1s) X-ray photoelectron spectroscopy (XPS) and near-edge X-ray absorption fine structure (NEXAFS) spectroscopy of predicted adsorbed structures have been simulated by density functional theory with cluster model calculations. Both XPS and NEXAFS spectra demonstrate the structural dependence on different adsorption configurations. In contrast to the XPS spectra, it is found that the NEXAFS spectra exhibiting conspicuous dependence on the structures of all the studied pyrazine/Si(100) systems can be well utilized for structural identification. In addition, according to the classification of carbon atoms, the spectral components of carbon atoms in different chemical environments have been investigated in the NEXAFS spectra as well.