172 research outputs found
Appearance of effective surface conductivity - an experimental and analytic study
Surface conductance measurements on p-type doped germanium show a small but
systematic change to the surface conductivity at different length scales. This
effect is independent of the structure of the surface states. We interpret this
phenomenon as a manifestation of conductivity changes beneath the surface. This
hypothesis is confirmed by an analysis of the classical current flow equation.
We derive an integral formula for calculating of the effective surface
conductivity as a function of the distance from a point source. Furthermore we
derive asymptotic values of the surface conductivity at small and large
distances. The actual surface conductivity can only be sampled close to the
current source. At large distances, the conductivity measured on the surface
corresponds to the bulk value.Comment: 11 pages, 8 figure
Fermi level pinning at the Ge(001) surface - A case for non-standard explanation
To explore the origin of the Fermi level pinning in germanium we investigate
the Ge(001) and Ge(001):H surfaces. The absence of relevant surface states in
the case of Ge(001):H should unpin the surface Fermi level. This is not
observed. For samples with donors as majority dopants the surface Fermi level
appears close to the top of the valence band regardless of the surface
structure. Surprisingly, for the passivated surface it is located below the top
of the valence band allowing scanning tunneling microscopy imaging within the
band gap. We argue that the well known electronic mechanism behind band bending
does not apply and a more complicated scenario involving ionic degrees of
freedom is therefore necessary. Experimental techniques involve four point
probe electric current measurements, scanning tunneling microscopy and
spectroscopy.Comment: 5 pages, 4 figure
Effect of selected drugs used in asthma treatment on morphology and elastic properties of red blood cells
Anna Zuk, Marta Targosz-Korecka, Marek SzymonskiResearch Centre for Nanometer-Scale Science and Advanced Materials, Faculty of Physics, Astronomy, and Applied Computer Science, Jagiellonian University, Reymonta 4, 30-059 Krakow, PolandBackground: The main function of red blood cells is to transport oxygen to all parts of the body with the help of hemoglobin. Other proteins of the cell membrane can attach xenobiotics (eg, drugs) from the blood and transport them throughout the body. Only drugs able to bind to the membrane of the red blood cell can modify its structure and elastic properties. The morphology and local elastic properties of living red blood cells incubated with drug solutions commonly used in the treatment of severe asthma were studied by atomic force microscopy and nanoindentation with an atomic force microscopy tip.Methods: The elasticity modules of native red blood cells, as well as those incubated with two types of drugs, ie, aminophylline and methylprednisolone, were determined from experimentally measured nanoindentation curves.Results: The elasticity modules of erythrocytes incubated with aminophylline were substantially higher than those obtained for nonincubated native, ie, healthy, red blood cells.Conclusion: The increase of the elasticity module obtained for aminophylline can reduce the cell's ability to bind oxygen and transport it through capillaries.Keywords: nanoindentation, atomic force microscopy, erythrocytes, elasticity, asthm
Quantitative analysis methods for studying fenestrations in liver sinusoidal endothelial cells. A comparative study
Liver Sinusoidal Endothelial Cells (LSEC) line the hepatic vasculature providing blood filtration via transmembrane nanopores called fenestrations. These structures are 50−300 nm in diameter, which is below the resolution limit of a conventional light microscopy. To date, there is no standardized method of fenestration image analysis. With this study, we provide and compare three different approaches: manual measurements, a semi-automatic (threshold-based) method, and an automatic method based on user-friendly open source machine learning software. Images were obtained using three super resolution techniques – atomic force microscopy (AFM), scanning electron microscopy (SEM), and structured illumination microscopy (SIM). Parameters describing fenestrations such as diameter, area, roundness, frequency, and porosity were measured. Finally, we studied the user bias by comparison of the data obtained by five different users applying provided analysis methods
Scanning probe microscopy studies on the adsorption of selected molecular dyes on titania
Titanium dioxide, or titania, sensitized with organic dyes is a very attractive platform for photovoltaic applications. In this context, the knowledge of properties of the titania–sensitizer junction is essential for designing efficient devices. Consequently, studies on the adsorption of organic dyes on titania surfaces and on the influence of the adsorption geometry on the energy level alignment between the substrate and an organic adsorbate are necessary. The method of choice for investigating the local environment of a single dye molecule is high-resolution scanning probe microscopy. Microscopic results combined with the outcome of common spectroscopic methods provide a better understanding of the mechanism taking place at the titania–sensitizer interface. In the following paper, we review the recent scanning probe microscopic research of a certain group of molecular assemblies on rutile titania surfaces as it pertains to dye-sensitized solar cell applications. We focus on experiments on adsorption of three types of prototypical dye molecules, i.e., perylene-3,4,9,10-tetracarboxylic dianhydride (PTCDA), phtalocyanines and porphyrins. Two interesting heteromolecular systems comprising molecules that are aligned with the given review are discussed as well
Photoinduced Br Desorption from CsBr Thin Films Grown on Cu(100)
Thin films of CsBr deposited onto metals such as copper are potential photocathode materials for light sources and other applications. We investigate desorption dynamics of Br atoms from CsBr films grown on insulator (KBr, LiF) and metal (Cu) substrates induced by sub-bandgap 6.4 eV laser pulses. The experimental results demonstrate that the peak kinetic energy of Br atoms desorbed from CsBr/Cu films is much lower than that for the hyperthermal desorption from CsBr/LiF films. Kelvin probe measurements indicate negative charge at the surface following Br desorption from CsBr/Cu films. Our ab initio calculations of excitons at CsBr surfaces demonstrate that this behavior can be explained by an exciton model of desorption including electron trapping at the CsBr surface. Trapped negative charges reduce the energy of surface excitons available for Br desorption. We examine the electron-trapping characteristics of low-coordinated sites at the surface, in particular, divacancies and kink sites. We also provide a model of cation desorption caused by Franck-Hertz excitation of F centers at the surface in the course of irradiation of CsBr/Cu films. These results provide new insights into the mechanisms of photoinduced structural evolution of alkali halide films on metal substrates and activation of metal photocathodes coated with CsBr
Measurement of the velocity distribution of sputtered Na atoms from NaCl by Doppler shift laser fluorescence
The velocity distribution of sputtered Na atoms from NaCI during 15 keV, Ar+ bombardment was measured by a Doppler shift laser fluorescence technique. Contrary to other measurements, the sputtered Na atoms were found to have a velocity distribution identical to that of a three-dimensional Maxwell-Boltzmann gas.Peer reviewedElectrical and Computer Engineerin
LSEC Fenestrae Are Preserved Despite Pro-inflammatory Phenotype of Liver Sinusoidal Endothelial Cells in Mice on High Fat Diet
Healthy liver sinusoidal endothelial cells (LSECs) maintain liver homeostasis, while LSEC dysfunction was suggested to coincide with defenestration. Here, we have revisited the relationship between LSEC pro-inflammatory response, defenestration, and impairment of LSEC bioenergetics in non-alcoholic fatty liver disease (NAFLD) in mice. We characterized inflammatory response, morphology as well as bioenergetics of LSECs in early and late phases of high fat diet (HFD)-induced NAFLD. LSEC phenotype was evaluated at early (2–8 week) and late (15–20 week) stages of NAFLD progression induced by HFD in male C57Bl/6 mice. NAFLD progression was monitored by insulin resistance, liver steatosis and obesity. LSEC phenotype was determined in isolated, primary LSECs by immunocytochemistry, mRNA gene expression (qRT-PCR), secreted prostanoids (LC/MS/MS) and bioenergetics (Seahorse FX Analyzer). LSEC morphology was examined using SEM and AFM techniques. Early phase of NAFLD, characterized by significant liver steatosis and prominent insulin resistance, was related with LSEC pro-inflammatory phenotype as evidenced by elevated ICAM-1, E-selectin and PECAM-1 expression. Transiently impaired mitochondrial phosphorylation in LSECs was compensated by increased glycolysis. Late stage of NAFLD was featured by prominent activation of pro-inflammatory LSEC phenotype (ICAM-1, E-selectin, PECAM-1 expression, increased COX-2, IL-6, and NOX-2 mRNA expression), activation of pro-inflammatory prostaglandins release (PGE2 and PGF2α) and preserved LSEC bioenergetics. Neither in the early nor in the late phase of NAFLD, were LSEC fenestrae compromised. In the early and late phases of NAFLD, despite metabolic and pro-inflammatory burden linked to HFD, LSEC fenestrae and bioenergetics are functionally preserved. These results suggest prominent adaptive capacity of LSECs that might mitigate NAFLD progression
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