Table of Contents |
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81 | Full Research Paper |
11 | Letter |
3 | Review |
5 | Editorial |
1 | Commentary |
Figure 1: The structure of the ordered phases with Strukturbericht designation “D022” (prototype structure: Al...
Figure 2: The vertical lines in the plot represent equipotential lines of the free energy for constant differ...
Figure 3: Calculated phase diagrams of Pt–Rh for three different particle sizes of 9201, 2075 and 807 atoms, ...
Figure 4: Equilibrium configurations of large particles with 9201 atoms at different concentrations and tempe...
Figure 5: Calculated phase diagram of bulk Pt–Rh (solid line) in comparison to that of a particle consisting ...
Figure 6:
All concentration-averaged Warren–Cowley short-range order parameters up to 8th neighbors for a Pt...
Figure 7:
Comparison of the (lower points) and
(upper points) WC-order parameters versus temperature for di...
Figure 8:
Comparison of the concentration-averaged order parameters (lower points) and
(upper points). The ...
Figure 9:
Comparison of the WC-order parameters (lower points) and
(upper points). The Pt concentration is ...
Figure 10:
Comparison of the order parameters (lower points) and
(upper points) constrained to a core region...
Figure 11:
Comparison of the 8 WC-order parameters and
of three different particle sizes and bulk material a...
Figure 12:
Comparison of the 8 averaged WC-order parameters of three different particle sizes and bulk materi...
Figure 1: A schematic drawing of the target molecules along with their acronyms.
Figure 2: S 2p (a), C 1s (b), and N 1s (c) HRXPS spectra of the target SAMs acquired at photon energies of 35...
Figure 3: (a) C K-edge NEXAFS spectra of the NC-OPEn SAMs acquired at an X-ray incidence angle of 55°. (b) Di...
Figure 4: π*-resonance photon-energy range of the C K-edge NEXAFS spectra of the target SAMs and two referenc...
Figure 5: (a) N K-edge NEXAFS spectra of the NC-OPEn SAMs acquired at an X-ray incidence angle of 55°. (b) Di...
Figure 6: Orientation of the NC-OPEn molecules in the respective SAMs (by the example of NC-OPE3; a planar co...
Figure 7: Calculated C K-edge NEXAFS spectra of NC-OPE3 in the planar and twisted conformations, along with t...
Figure 8: Calculated N K-edge NEXAFS spectra of NC-OPE3 in the planar and twisted conformations, along with t...
Figure 1: Topographs acquired in constant Δf NC-AFM of Si(100) at 5 K, demonstrating different imaging mechan...
Figure 2: Larger scans of (a) inverted and (b) high-setpoint inverted images presented in Figure 1b and Figure 1c. In a) the la...
Figure 3: Experimental short-range force (nN) and dissipation (eV/cycle) as a function of relative tip–sample...
Figure 1: [Bmim]Cl assembles on the OTSpd pattern. a) OTSpd discs fabricated by scanning probe deep oxidation...
Figure 2: a) A representative OTS-coated [Bmim]Cl drop on the OTSpd pattern. AC mode topography image. b) Opt...
Figure 3: H2O2 decomposition reaction catalyzed by FeCl3. The process was recorded by the optical microscope ...
Figure 1: Spectral functions A(E) = −(1/π)Tr{G(E)} at room temperature for gas-phase benzene (top panel) and ...
Figure 2: Calculated van der Waals contribution to the binding energy of benzene adsorbed on a Pt(111) surfac...
Figure 3: The trace of Γα for a Pt electrode in contact with a benzene molecule. Nine total basis states of t...
Figure 4: Eigenvalue decomposition of an ensemble of Γα matricies, showing that each lead–molecule contact ha...
Figure 5:
The distribution of charging energy (top panel) and Tr{Γ} (bottom panel) over the ensemble describ...
Figure 6: Calculated conductance histogram for the ensemble over bonding configurations and Pt surfaces. The ...
Figure 7: The calculated eigenvalue distributions for an ensemble of 1.74 × 105 (2000 bonding configurations ...
Figure 8: The calculated average total transmission averaged over 2000 bonding configurations through a Pt–be...
Figure 9: The calculated Fano factor F distribution for the full ensemble of 1.74 × 105 Pt–benzene–Pt junctio...
Figure 1: (a) Schematic of the tDPN process which uses a heated scanning probe microscope tip to deposit poly...
Figure 2: Orientations of UHV deposited polymer. (a) PDDT typically organizes in such way that the polymer is...
Figure 3: The polymer deposit heights and widths of PDDT deposited onto Si substrate (non-UHV prepared) as a ...
Figure 4: (a) Deposition onto the UHV prepared Si substrate in UHV shows the polymer lying on its side. (b) P...
Figure 1: Plant surfaces investigated showing different types of structuring. Pictograms on the top show the ...
Figure 2: Traction forces of actively walking male Leptinotarsa decemlineata beetles on plant surfaces of dif...
Figure 3: SEM micrographs of the attachment devices in a male Leptinotarsa decemlineata. (a) Ventral view of ...
Figure 4: Experimental setup. Traction forces of a beetle (b) actively walking on a plant surface (p) were re...
Figure 1: Schematic diagram of the process flow: (a) SAM formation upon immersion in an ethanolic solution of...
Figure 2: UV–vis spectra of Au/glass substrates with Au layer thicknesses of 10 nm, 30 nm and 50 nm.
Figure 3: IRRAS-spectra of an HDT-coated Au/glass substrate exposing a 50 nm Au layer.
Figure 4: Optical micrograph of a laser-fabricated dot pattern. HDT-SAMs on a Au/glass substrate exposing a 3...
Figure 5: AFM data from patterning experiments with HDT-SAMs on Au/glass substrates exposing a 30 nm thick Au...
Figure 6: Dependence of the structure diameter d on the incident laser power P and the pulse length τ of HDT-...
Figure 7: (a) Calculated stationary temperature profiles on different types of Au-coated substrates used for ...
Figure 8: Optical micrograph of a laser-patterned HDT SAM on a Au/glass substrate exposing a 10 nm thick Au l...
Figure 1: TEM images of (a) Co@OA, (b) Co@PCL, (c) Co@PS particles.
Figure 2: Magnetization graphs of toluene-based particle dispersions sampled at selected points of storage ti...
Figure 3: Relative saturation magnetization Ms/Ms,0 of toluene-based particle dispersions sampled as a functi...
Figure 4: Relative initial susceptibility χini/χini,0 of toluene-based particle dispersions sampled as a func...
Figure 5: Magnetization graphs of Co@PCL particles at selected points of storage time at 25 °C in air, normal...
Figure 6: Quasi-static magnetization curves of Co@PS based particles exposed to air (a) in dispersion and (b)...
Figure 7: Magnetic properties of Co@PCL and Co@PS particles as a powder, as a function of storage time. (a) R...
Figure 1: Schematic illustration of imogolite-nanotube structure (left). DFM image of imogolite (right).
Figure 2: Monoclinic solid-state packing arrangement of the imogolite nanotubes.
Figure 3: Purification steps of imogolite from imogo soil.
Figure 4: Schematic illustration of dodecylphosphate chemisorbing onto the surface of individually dispersed ...
Figure 5: Thermogravimetric profiles of the original imogolite, DDPO4H2, and DDPO4-imogolite in N2 atmosphere...
Figure 6: High-resolution XPS spectra for Al2p of the original imogolite and DDPO4-imogolite. Adapted with pe...
Figure 7: WAXD profiles of (a) original imogolite and (b) DDPO4-imogolite. Adapted with permission from W. Ma...
Figure 8: TEM image of DDPO4-imogolite. Reprinted with permission from W. Ma et al., Chem. Lett. 2011, 40, 15...
Figure 9: Static-contact-angle images of water droplets on a silicon wafer cast with (a) original imogolite a...
Figure 10: Schematic representation for the preparation of a PMMA grafted imogolite nanotubes. Reprinted with ...
Figure 11: Chemical structure of BMPOPO4(NH4)2. Reprinted with permission from W. Ma et al., Polymer 2011, 52,...
Figure 12: Wide-scan XPS spectra of the original imogolite and BMPOPO4-imogolite (inset, high-resolution XPS s...
Figure 13: (a) A SFM height image of PMMA grafted imogolite (Mn = 32700, Mw/Mn = 1.33). (b) A phase image (ins...
Figure 14: WAXD profiles of (a) quartz-glass capillary background, (b) bare imogolite, (c) BMPOPO4-imogolite, ...
Scheme 1: Synthesis pathway for electron donating (HT3P) and accepting (HT3OP) terthiophene of phosphonic aci...
Figure 15: Schematic illustration of imogolite structure and the preparation of terthiophene/imogolite hybrid ...
Figure 16: FTIR spectra (a) of HT3P/imogolite hybrid, HT3P, and imogolite, (b) of HT3OP/imogolite hybrid, HT3O...
Figure 17: Normalized solid-state (cast film), imogolite hybrid and solution absorption spectra of (a) HT3P an...
Figure 18: Fluorescence excitation/emission spectra of (a) HT3P, HT3P/imogolite hybrid and (b) HT3OP, HT3OP/im...
Figure 19: I–V curves of imogolite, HT3P/imogolite, and HT3OP/imogolite hybrid. Reprinted with permission from...
Figure 20: Schematic illustration of reversible formation of P3HT nanofiber.
Figure 21: Fabrication and proposed molecular arrangement of P3HT/HT3P-imogolite nanofiber hybrid. Reprinted w...
Figure 22: UV–vis absorption spectra of P3HT (a) and P3HT/HT3P-imogolite hybrid (b) in anisole (0.0005%) durin...
Figure 23: DFM images of (a) P3HT nanofiber and (b) P3HT/HT3P-imogolite nanofiber hybrid. Adapted with permiss...
Figure 24: Out-of-plane (a) and in-plane (b) GIWAXD patterns of P3HT/HT3P-imogolite nanofiber hybrid. (c) Sche...
Figure 1: (a) Scheme of SAM controlled electrodeposition and lift-off of metal structures. Starting from a un...
Figure 2: (a) Illustration of different types of defects in a SAM. Domain boundaries (1) and substrate steps ...
Figure 3: Linear-sweep voltammograms comparing the electrodeposition of Cu on clean (black squares) and SAM m...
Figure 4: (a,b) Chronoamperograms of single potential (a) and double potential (b) deposition processes on a ...
Figure 5: SEM images of Cu nucleation and growth on a MBP0-SAM on Au/Ag/Mica prepared at 65 °C for 24 h. (a) ...
Figure 6: Electrochemical deposition of Cu on e-beam-patterned MBP0-SAM/Au/Si. (a) SEM image of a series of p...
Figure 7: SEM images of a SAM templated copper deposit on the original MBP0 coated Au/Si substrate (a) and af...
Figure 8: AFM topography images of Cu electrodeposited onto an e-beam-patterned MBP0-SAM on Au/Si (a) before ...
Figure 9: AFM images of Cu electrodeposition onto a MBP0/Au/Si sample demonstrating the quality of passivatio...
Figure 10: (a,b) AFM topography images and height profiles along the lines indicated, comparing the roughness ...
Figure 1: Strategies for preparing organosilane nanostructures by means of particle lithography. Basic steps ...
Figure 2: Combining particle lithography with vapor deposition of OTS produced ring-shaped nanostructures. (a...
Figure 3: Particle lithography with vapor deposition of OTS produced multilayered ring nanostructures surroun...
Figure 4: Nanopore structures of OTS were formed with particle lithography combined with contact printing. Co...
Figure 5: Nanodots of OTS produced with immersion of annealed latex masks. Contact-mode AFM images are shown ...
Figure 6: Nanostructured film of OTS produced by immersion of annealed silica masks in OTS solutions. Contact...
Figure 1: XRD patterns of (a) the KLE-templated mesoporous and (b) the nonporous MgTa2O6 thin film after ther...
Figure 2: Average grain size and its standard deviation as a measure of anisotropy of MgTa2O6 in the mesoporo...
Figure 3: SEM surface morphologies of a mesoporous KLE-templated MgTa2O6 film after thermal treatment at (a) ...
Figure 4: AFM (a, c) morphology of the KLE-templated mesoporous MgTa2O6 film after calcination at 760 °C. The...
Figure 5: TEM morphology of a fragment scratched off from a mesoporous KLE-templated MgTa2O6 thin film before...
Figure 6: SAXS patterns (measured in symmetric reflection) of the mesoporous KLE-templated MgTa2O6 thin film ...
Figure 7: 2-D-SAXS patterns of the KLE-templated mesoporous MgTa2O6 thin film after calcination at various te...
Figure 8: (a) Absorption spectra of RhB after photodegradation for given durations, assisted by the mesoporou...
Figure 9: Reaction rate constants of the photodegradation reaction in the presence of the KLE-templated mesop...
Figure 1: Scheme of parallel-contact electrochemical metallization of a OTSeo@OTS/Si template nanopattern (ta...
Figure 2: SFM images (and distance–height profiles along the marked lines) acquired after each step during th...
Figure 3: Semicontact SFM images (and distance–height profiles along the marked lines) of different silver/mo...
Figure 4: Scheme of serial-contact electrochemical metallization of selected sites within the OTSeo lines of ...
Figure 5: Fabrication of a rectangular array of 30 silver/monolayer nanodots by the serial CET process outlin...
Figure 6: Proposed bipolar electrochemical mechanism of metal transfer from a thin, granular silver-film stam...
Figure 1:
Resonant level. The shape of the effective potential can be tuned by the bias voltage. We consider...
Figure 2: Sketch of the two-level model. Electrons tunnel through two degenerate energy levels between the le...
Figure 3: Effective potential for the mechanical motion in the two-level model. The shape of the potential ca...
Figure 4: Damping versus mechanical displacement in the two-level model. (a) Contribution γs,eq to the fricti...
Figure 5: Cartoon of the positions of the electronic levels in the dot with respect to the Fermi levels of th...
Figure 6: Dependence of the current in the two-level model on various parameters. Current as a function of me...
Figure 7: Curl of the average force and damping coefficient for the model with two vibrational modes: (a) The...
Figure 8: Limit-cycle dynamics for the model with two vibrational modes. (a) At large bias voltages, Poincaré...
Figure 9: Current–current correlation function in the presence of noise for the system with two vibrational m...
Figure 1: The artificial cilium is made of superparamagnetic beads. An external magnetic field is used to act...
Figure 2: Fluid flow around a beating artificial cilium. The cilium was anchored to the surface at (0,0) and ...
Figure 3: The time- and position-averaged flow velocities that were obtained for a variety of beating paramet...
Figure 4: Calculated fluid flow around a beating cilium in the far-field approximation. Blue arrows indicate ...
Figure 5: Magneto-optical tweezers used in the experiment. Three pairs of water-cooled coils ensured an almos...
Figure 1: (a) MFM probes the force between the magnetic dipole moment of a probe tip and the magnetic stray f...
Figure 2: Lift Mode FM-MFM image using a qPlus sensor with an etched iron tip attached to it (see inset in a)...
Figure 3: Lift Mode FM-MFM image employing a qPlus sensor with a commercial cobalt-coated MFM cantilever tip ...
Figure 1: Topography images of the SiC(0001) sample (a) before annealing, (b) after oxide removal at 1000 °C,...
Figure 2: Topography images of graphene layers epitaxially grown on SiC(0001); (a) preparation in UHV, (b) pr...
Figure 3: (a) Topographic image showing two steps found typically on samples prepared in an argon atmosphere....
Figure 4: Rendered images of graphene layers on SiC(0001) prepared in (a) UHV and (b) an argon atmosphere. Th...
Figure 5: Two-dimensional histograms based on the data set for the rendered images in Figure 4. The colour scheme rep...
Figure 1: (a) SFM image showing part of a large pentacene island that overgrows two monoatomic substrate step...
Figure 2: Pattern I. Imaged with an angle of 45°. (a) Topograph. (b) Simultaneously acquired dissipation sign...
Figure 3: Pattern II. (a) Image displaying a defect. (b) Imaged with an angle of 45°. (c) Magnification of th...
Figure 4: Large-area scan of the area where Figure 2 and Figure 3 were recorded with molecular resolution. f0 = 160.440 kHz, Δ...
Figure 1: (a) Ball model of the MgAl2O4 stacking sequence in the [111] direction showing one repeat unit of 4...
Figure 2: Experimental NC-AFM images recorded on the MgAl2O4(111) surface prepared by sputtering and annealin...
Figure 3: (a) Experimental NC-AFM image with the surface superstructure model superimposed. (b) Illustration ...
Figure 1: (a) Scheme of the first two eigenmodes of a cantilever and the tip deflection under bimodal excitat...
Figure 2: Fractional operators of (0.14/x6 − 1/x2). (a) The function, half-derivative and derivative are plot...
Figure 3: Comparison between the general expression (Equation 6) and the half-derivative (Equation 16) relationship to the frequen...
Figure 4: Comparison between the general expression (Equation 23) and the half-integral relationship (Equation 24) to the frequency...
Figure 5: Comparison between the general expression for the frequency shift of the second mode in bimodal FM-...
Figure 1: (a) STM image of the PTCDA/Ag/Si(111) √3 × √3 surface. Scan area: 250 nm × 250 nm, tunneling voltag...
Figure 2: STM image of a double layer of PTCDA arranged in a herringbone phase. The structure is indicated by...
Figure 3: (a) Frequency-shift versus distance curve. The contribution from the long-range forces has been sub...
Figure 4: Scheme of the dissipation processes. The black arrows mark the different “snapshots” for the approa...
Figure 5: (a) Dissipation signal for approach (black dots) and retraction (red dots). The inset displays the ...
Figure 1: Trichlorosilyl thioesters.
Figure 2: Thickness and contact angles (advancing/receding) for SAMs based on compounds 1b–i.
Figure 3: UV–vis spectra of SAMs of compounds 1a, 2, 3 and 4.
Figure 4: Representative sulfur XPS analyses of the SAMs of compounds 2 (A), 3 (B) and 4 (C).
Figure 5: ATR–FTIR spectra of SAMs of compounds 1a, 2, 3 and 4, as deposited, and after oxidation with UV-A i...
Figure 1: (a) Molecular scheme and (b) structure of HCPTP optimized in vacuum.
Figure 2: Constant-frequency-shift image of the KBr surface after the deposition of a small amount of molecul...
Figure 3: Upper image: topography and lower image: Kelvin map of a KBr terrace with a higher coverage. Imagin...
Figure 4: Images of a sample annealed at 150 °C after the deposition of the molecules at room temperature. (a...
Figure 5: (a) and (b) are the profiles that correspond to the blue and green lines drawn in Figure 4a; (c) is the prof...
Figure 6: (a) Topographic and (b) Kelvin map of a high molecular coverage annealed to 150 °C; (c) and (d) are...
Figure 7: High resolution topographic images of an MLh domain. A = 2 nm. (a) Δf = −35 Hz, (b) Δf = −50 Hz. Th...
Figure 8: High resolution (a) topographic and (b) Kelvin image of an MLv domain. A = 2 nm, Δf = −20 Hz. The a...
Figure 9: Lowest-energy adsorbed conformation of HCPTP adsorbed on KBr(001). (a) Top and (b) side view. K+ io...
Figure 10: Tentative model of the MLh layer.
Figure 1: AFM resolution examples: (a) high resolution UHV NC-AFM image of SiO2 displaying features with radi...
Figure 2: Verification of atom–substrate potential: Potential wa–s versus z for numerical and analytical sche...
Figure 3: Schematic illustrating the model geometry: The surface is sinusoidally corrugated along the x direc...
Figure 4: Hamaker force for flat surfaces: Relationship between tip potential and distance from the surface. ...
Figure 5: Hamaker force law for corrugated surfaces: Tip–sample distance dependence of tip potential for high...
Figure 6: Contours of constant normalized frequency shift, γ, for a corrugated surface. Attenuation is observ...
Figure 1: (a) Definition of the z-axis: The cantilever oscillates with a constant amplitude A. The lower turn...
Figure 2: Amplitude dependence of the CoD for the Morse force law. The positions marked with 1, 2, 3, and 4 c...
Figure 3: Model force Fts(z), deconvoluted force FS/M(z) and the residuals ΔFS/M(z) for the Morse force law w...
Figure 4: Amplitude dependence of the deviation in magnitude (a) and position (b) from the force minimum for ...
Figure 5: Amplitude dependence of the CoD for a Lennard-Jones force law. The positions marked with 1, 2, 3, a...
Figure 6: Model force Fts(z), deconvoluted force curves FS/M(z) and the residuals ΔFS/M(z) for the Lennard-Jo...
Figure 7: Amplitude dependence of the deviation in magnitude (a) and position (b) from the force minimum for ...
Figure 8: Dependence of the CoD on the ratio A/d of amplitude and step width for the Morse and the Lennard-Jo...
Figure 9: (a) Amplitude dependence of the CoD for Morse force law with different decay constants κ (see legen...
Figure 1: The effect of z modulation (A) on the tunneling current (B). amod = 0.1 nm and f0 = 73180 Hz; It ca...
Figure 2: Circuit diagram of a current-to-voltage converter (IVC) where Rf is the feedback resistance with th...
Figure 3: (A) Frequency response of the IVC presented in Figure 2. The following parameters were used to simulate Rf ...
Figure 4: (A) The coupling between the deflection and the tunneling current channel is established by the str...
Figure 5:
(A) If the slow Op111 is replaced by a faster OPA, Op637, the modulation of the virtual ground can...
Figure 6: (A) Original connections in which one of the electrodes of the tuning fork was connected to the def...
Figure 7: A set of constant-frequency-shift maps (z) and simultaneously recorded average-tunneling-current ma...
Figure 8: Two typically observed profiles of the dependence of the short-range interaction force (FSR) and th...
Figure 9: Analyses of the impact of the tunneling current on dissipation. It can be clearly seen that the tun...
Figure 10: Relationship between the frequency shift and the dissipation for the reactive tip termination (A) a...
Figure 11: Corrected dissipation for damping measured above the adatom and above the corner hole. The corner h...
Figure 1: Schematic diagram of cantilever regulation by means of magnetic force. The system consists of a Q-c...
Figure 2: Transfer function of the differentiator in the Q-control circuit with a cutoff frequency of about 8...
Figure 3: Effect of Q-control on the step-response of the cantilever recorded at about 700 nm from a mica sub...
Figure 4: Comparison of the power spectrum density (PSD) of thermal noise in the cantilever-deflection signal...
Figure 5: Comparison of pulse responses recorded at 300 nm from the substrate (a) and in close proximity (b)....
Figure 6: Complex compliance of cantilever–water system calculated by Fourier–Laplace transformation of the r...
Figure 7: Derivation of the viscoelasticity of hydrated water. The compliance data shown in Figure 6 are inverted to ...
Figure 1: Coating installation.
Figure 2: XRD diffraction pattern of NPs of KI coated on a silicon wafer (the red lines indicate literature d...
Figure 3: XRD diffraction pattern of NaCl precipitate collected at the end of sonication (red lines indicate ...
Figure 4: Raman spectrum of a silicon wafer and a silicon wafer coated with CuSO4.
Figure 5: K (top) and I (bottom) XPS spectra detected from the glass coated with KI.
Figure 6: The SEM images of (a) pristine microscope glass slide (magnification 20000×); (b) the glass slide c...
Figure 7: SEM images of (a) parylene-coated glass slide (magnification 20000×); (b) parylene-coated glass sli...
Figure 8: Size distribution measurements of a 0.08 M NaCl solution after sonication.
Figure 9: 3D AFM image of the microscope slide after sonication (30 min) in doubly distilled water; (b) 3D AF...
Figure 10: The AFM images of (a) parylene-coated glass slide before the sonication process; (b) parylene-coate...
Figure 11: Scheme of the sonochemical deposition of inorganic salt nanoparticles on the solid substrate.
Figure 1: XPS measurements on Cu3BiS3 and Cu3BiS3 etched in NH3. (a) Overview spectrum showing that Na, oxide...
Figure 2: KPFM measurements of the (from left to right) NH3-etched Cu3BiS3, and Cu3BiS3 with the In2S3, ZnS a...
Figure 3: Overview of the measured work-function values and their distribution for all samples investigated. ...
Figure 4: In-phase (solid circles) and 90°-phase-shifted (open circles) SPV spectra of (a) Cu3BiS3 and (b) Cu3...
Figure 5: PV amplitude spectra of (a) Cu3BiS3 and (b) Cu3BiS3/In2S3 at modulation frequencies between 3.5 and...
Figure 1: MSPS can have two conformations, namely the agraffe-like cis (a) and the scorpion-like trans (b) is...
Figure 2: 0.2 ML of MSPS evaporated onto KCl. (a) displays the NC-AFM topography after deposition at RT (Δf =...
Figure 3: (a) Topography image of ≈1 ML of MSPS adsorbed on KCl (Δf = −75 Hz, A0 = 7 nm); (b) shows a close u...
Figure 4: Conformations of MSPS on KCl(001). Only the positions of the substrate anions have been drawn. In (...
Figure 5: Model for the lateral stress ε in a MSPS film adsorbed on KBr (left) and NaCl (right). (a) and (d) ...
Figure 6: (a) Large-scale topography image of electron-bombarded KCl showing the characteristic holes (Δf = −...
Figure 1: The response of a damped harmonic oscillator (red line) to a chirped driver (blue line) whose frequ...
Figure 2: Wavelet cross-correlation between the chirped driver and the response of the damped harmonic oscill...
Figure 3: The response of a damped harmonic oscillator (red line, quality factor Q = 4) to a sinc driver (blu...
Figure 4: Wavelet cross-correlation between the sinc driver and the response of the damped harmonic oscillato...
Figure 5: The response of a damped harmonic oscillator (red line, quality factor Q = 40) to a sinc driver (bl...
Figure 6: Wavelet cross-correlation between the sinc driver and the response of the damped harmonic oscillato...
Figure 7: Wavelet cross-correlation between a sinusoidal reference signal at resonance and the damped harmoni...