Table of Contents |
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211 | Full Research Paper |
7 | Letter |
27 | Review |
10 | Editorial |
2 | Commentary |
3 | Correction |
Figure 1: (a) X-ray fluorescence spectrum in the L-line energy range of Ag, where the green lines are the ind...
Figure 2: Grazing incidence X-ray diffraction spectrum taken at the beginning of the irradiation process of Figure 1c....
Figure 3: Grazing incidence X-ray diffraction spectrum taken after two hours into the irradiation process of Figure 1c...
Figure 4: Grazing incidence X-ray diffraction spectrum taken after 15 h into the irradiation process of Figure 1c. Top...
Figure 1: A ball–stick model of tris(2,2,6,6-tetramethyl-3,5-heptanedionato) lanthanide(III).
Figure 2: STM topographies of Tb(thd)3 (a,b) on Cu(111), (c,d) on Ag(111), and (e,f) on Au(111). The image si...
Figure 3: STM topographies of Tb(thd)3 films (a) on Cu(111) and (b) on Ag(111) with the model of the substrat...
Figure 4: (a) dI/dV spectra of a molecule in a trimer (black line) and on the Au substrate (blue line). (b) S...
Figure 1: (a) Differential conductance vs applied bias voltage (dI/dV vs V) measured for a silver/copper–phth...
Figure 2: (a) Differential conductance curves measured during the elongation process of the junction. The red...
Figure 3: Conductance–length histograms, indicating the most probable conductance of the junction during the ...
Figure 1: Schematic of the experimental setup consisting of a reservoir, pump, photoreactor and irradiator.
Figure 2: The photoreactor placed in front of the irradiator and the UV intensity distribution on the illumin...
Figure 3: Apparent reaction rate constant K for the whole system and the intrinsic reaction rate constant k i...
Figure 4: Aggregate size of P25 as a function of ultrasonic energy density performed by two ultrasonic device...
Figure 5: (a) Light transmittance (T) through a 1 cm optical path length and (b) extinction coefficient (ε) o...
Figure 6: Dependence of MB discoloration in 1 g/L P25 suspensions on the photocatalyst aggregate size achieve...
Figure 7: Influence of P25 catalyst concentration on the reaction rate constant and the transmittance through...
Figure 1: Schematic illustration of the experimental setup. The inset represents structural formula of mesity...
Figure 2: Conductance traces (a–c) and semi-logarithmic conductance histograms (d,e) during STM-BJ rupture pr...
Figure 3: Stretch length histograms on a semi-log scale constructed from 2000 of all conductance traces taken...
Figure 4: (a) 2D histogram of I–V curves of the mesitylene molecular junctions. The histogram is built from 1...
Figure 5: Proposed structural models of the mesitylene molecular junctions for (a) high-conductance and (b) l...
Figure 1: (a) Geometry and atomic composition of CuPc. (b) Single particle energies of relevant molecular orb...
Figure 2: Lowest lying anionic states of CuPc, together with their grade of degeneracy d. Without exchange an...
Figure 3: (a) Dependence of the single particle orbital energies on the magnetic field strength. From this, t...
Figure 4: Current and differential conductance curves exhibiting the anionic (cationic) resonance at positive...
Figure 5: Differential conductance maps as a function of the strength Bz of the magnetic field in z-direction...
Figure 6: Differential conductance maps vs the angle θ, formed by the applied magnetic field with the z-axis....
Figure 1: (a) SEM image of the ZnO nanorods grown on ≈100 nm thick, highly doped, patterned, p-type, silicon ...
Figure 2: The schematics of a typical measurement setup with a pulse generating unit (PGU). An optical spectr...
Figure 3: Frames extracted from high-speed videos showing light emission and changing percolation paths durin...
Figure 4: Frames extracted from high-resolution videos showing light emission from the ZnO nanorods contacted...
Figure 5: (a) Optical emission spectra obtained from DC voltage sweeping of 0–80 V (blue), AC excitation with...
Figure 6: (a) Spectrum of the light emission resulting from application of a single pulse with amplitude of 4...
Figure 7: Scanning electron microscope image of the molten path due to the current flow between the contacts ...
Figure 8: Optical microscope images showing two tungsten probes placed on a continuous ZnO nanoforest before ...
Figure 9: (a) I–V characteristics for two DC voltage sweep measurements from 0–60 V performed in vacuum (red)...
Figure 1: The geometrical structures of Sn, SnH, and SnF lattices from top (a–c) and side (d–f) views. Color ...
Figure 2: Minimum pathway for noble gases (He, Ne and Ar) penetrating through 2D Sn lattice under (a) 0%, (b)...
Figure 3: Minimum pathway for noble gases (He, Ne and Ar) passing through a 2D SnH lattice under (a) 0%, (b) ...
Figure 4: Minimum pathway for noble gases (He, Ne and Ar) passing through a 2D SnF lattice under (a) 0%, (b) ...
Figure 5: Diffusion rate (a) and selectivity (b) for noble gases (He, Ne and Ar) penetrating through 2D Sn, S...
Figure 1: (a) Schematic of the inelastic electron tunneling spectroscopy (IETS) in a single-molecule junction...
Figure 2: (a) Typical breaking traces recorded on a junction without molecule (left) and with OPE3 (right). (...
Figure 3: (a) Two-dimensional histograms of two configurations built from the individual spectra measured on ...
Figure 4: (a) Low-bias conductance trace recorded during the stretching of an OPE3 single-molecule junction (...
Figure 5: (a) Three selected geometries along the stretching of the junction. (b) Calculated vibrational spec...
Figure 6: Current versus time traces acquired at bias voltages varying between 0.14 and 0.24 V. The traces ha...
Figure 1: a) Schematic view of the optical path allowing good visibility from the top to the tip–sample setup...
Figure 2: Additional two lenses optics which allows for the illumination of the tip–sample interface.
Figure 3: Coarse positioner and scan unit. Panel a shows the entire unit. In panel b the unit is stripped dow...
Figure 4: The atomic force microscope is assembled on a CF200 flange with four tension springs. Copper fins a...
Figure 5: A chromium grain embedded in a polycrystalline copper alloy. a) Measured with a confocal laser micr...
Figure 6: a) Topography, b) dark KPFM and c) 30% laser-power illuminated (470–480 nm and a maximum power of 5...
Figure 7: Panel a shows sections across the SiC p/n-junction (Figure 6) extracted from images taken at various light ...
Figure 8: Simultaneously acquired topography (a) and CPD (b) images of a silicon carbide JBS structure. The s...
Figure 9: a) Close view of the line sections from Figure 8e at the top layer of the structure, together with least-squ...
Figure 1: Schematic representation of the concept of a dual electric/optical sensor made of a nanoparticle as...
Figure 2: (a) Optical image of the IDE (Dropsens) electrically connected by conductor wires; (b) Optical imag...
Figure 3: (a) Scheme of the experimental setup for chemiresistive detection; (b) Chemiresistor response: elec...
Figure 1: Sketch of terminating layer conformation for PLGA-PEI-PAA nanoparticles prepared at pH 3 in a) ultr...
Figure 2: Titration of PLGA–PEI–PAA nanoparticles with HCl (25 mM) for different pH values during assembly of...
Figure 3: Particle radii (bars) and zeta potential (line plot) of PLGA-PEI-PAA-PDADMAC nanoparticles in depen...
Figure 4: Hydrodynamic radii (bars) and zeta potential (line plot) in dependence of the number of polymer lay...
Figure 5: 1H NMR spectra of solutions (50 mM monomer conc.) of PDADMAC, PAA, PEI, and PVA (from top to bottom...
Figure 6: Released amount of PDADMAC per surface area in dependence of the pH. The amount of released PDADMAC...