- Full Research Paper
- Published 20 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Graphene: a) unit cell with electrodes; b) transmission function (green: dk = 0.1 1/Å, blue: dk = 0...
-
![]()
Figure 2: Transmission function: a) Т(Е) for three different ky; b) the distribution of points of the transmi...
-
![]()
Figure 3: Graphene transmission function: a) a map of T(E) for the initial partitioning over ky (from above) ...
-
![]()
Figure 4: Graphane transmission function: a) a map of T(E) for the initial partitioning over ky (top) and (bo...
-
![]()
Figure 5: 2D composite of pillared graphene based on CNT (9,9) with a length of 2.4 nm: a) atomic structure; ...
-
![]()
Figure 6: Two-layer 2D composite of pillared graphene based on CNT (9,9) with a length of 2.4 nm: a) atomic s...
-
![]()
Figure 7: Plots of the transmission functions for two-layer (blue) and single-layer (red) composites (the tub...
-
- Full Research Paper
- Published 19 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Crystal structure side view of (a) SiAs2 bulk (3 × 2 super cells) and (b) GeAs2 bulk (red: silicon,...
-
![]()
Figure 2: Phonon band structure of a monolayer of (a) SiAs2 and (b) GeAs2 along the high-symmetry points in t...
-
![]()
Figure 3: Band structure for SiAs2 and GeAs2 calculated by the HSE-Wannier function method. The Fermi level i...
-
![]()
Figure 4: Calculated light absorption spectrum of monolayers of SiAs2 (green) and GeAs2 (blue) using HSE func...
-
![]()
Figure 5: (a,c) GW-band structures and (b,d) BSE-optical absorption spectra of SiAs2 and GeAs2, respectively.
-
-
Supp. Info
- Full Research Paper
- Published 19 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Perspective snapshot of the formed nanoparticle containing 20000 Al atoms.
-
![]()
Figure 2: Time dependencies of temperature T of the system, velocity Vy and lateral position yCM of the cente...
-
![]()
Figure 3: Substrate force as a function of the lateral position of the center of mass of the nanoparticles: (...
-
![]()
Figure 4: Friction force as a function of the contact area with confidence intervals of the approximation at ...
-
![]()
Figure 5: Shear stress as a function of the contact area with confidence intervals of the approximation at a ...
-
![]()
Figure 6: A nanoparticle (green) on a substrate (black) when the interaction between the particle and the sub...
-
![]()
Figure 7: Side view of a Pd nanoparticle with 20000 atoms (the horizontal solid line is the graphene plane) a...
-
![]()
Figure 8: Friction force versus temperature with confidence intervals of the second-degree polynomial approxi...
-
![]()
Figure 9: Radial distribution function for the Al and Pd nanoparticles containing 20000 atoms for the bulk cr...
-
![]()
Figure 10: (A, C) Side and (B, D) bottom views of (A, B) Al and (C, D) Pd nanoparticles containing 20000 atoms...
-
- Full Research Paper
- Published 18 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Optofluidic chip is secured in a chip cassette and is permanently bonded to three optical fibers, w...
-
![]()
Figure 2: (A) Near-field light scattering with relevant forces acting on the particle. (B, C) Trapped particl...
-
![]()
Figure 3: TEM images of uncoated SPIOs (A), PEG-SPIOs (B) with scale bar of 20 nm. EDS spectrum of uncoated S...
-
![]()
Figure 4: Microscopy images of PEG-SPIOs in aqueous solution. The laser pushes the trapped nanoparticles acro...
-
![]()
Figure 5: (A) Intensity and velocity distributions of PEG-SPIOs (n = 47) and IPC-SPIOs n = 51), presented as ...
-
![]()
Figure 6: Velocity vs intensity. (A) Velocity of individual PEG- and IPC-coated SPIOs vs measured scattering ...
-
![]()
Figure 7: Measured velocity and drag force of the same particle in solution with different salt concentration...
-
- Full Research Paper
- Published 18 Apr 2018
-
PDF -
Album-
![]()
Figure 1: (a) Scanning electron micrograph of a FEBID pad. (b) Atomic force micrograph of the same pad. (c + ...
-
![]()
Figure 2: (a) Raman spectra of a FEBID pad, FEBID precursor and the substrate. The complex structure of the p...
-
![]()
Figure 3: (a) Real and (b) imaginary part of the dielectric function of the measured FEBID material, averaged...
-
![]()
Figure 4: (a + b) Scanning electron micrographs of a single nanopillar (a) and a copper helix with three pitc...
-
![]()
Figure 5: (a) Array of 8 × 8 nanocones with a distance of 400 nm, base diameter of 80 nm and a height of 250 ...
-
-
Supp. Info
- Full Research Paper
- Published 17 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Steps for preparing nanopatterned CMPS-porphyrin heterostructures. (a) Monodisperse silica spheres ...
-
![]()
Figure 2: Nanoholes within a thin film of OTS. (a) Topography frame, 3 × 3 µm2; and simultaneously acquired (...
-
![]()
Figure 3: Nanodots of CMPS grown in a solution of BCH. (a) Topography image, 3 × 3 μm2; (b) structural model ...
-
![]()
Figure 4: Heterostructures comprised of CMPS and H2TPyP porphyrin grown on Si(111) in BCH. (a) Topography ima...
-
![]()
Figure 5: Model for the self-assembly of CMPS-porphyrin heterostructures within an OTS matrix layer.
-
-
Supp. Info
- Full Research Paper
- Published 17 Apr 2018
-
PDF -
Album-
![]()
Figure 1: (a) Schematic of the preparation approach of HACC-rGO. (b) SEM image of the resulting HACC-rGO. (c)...
-
![]()
Figure 2: (a) Schematic illustration of the electrodeposition of HACC-rGO with chitosan on the copper electro...
-
![]()
Figure 3: (a) SEM image of the deposited HACC-rGO/CS film surface. (b) SEM image of the cross-section of the ...
-
![]()
Figure 4: Images of the cathodically electrodeposited film of HACC-rGO and chitosan on the copper plate (a) a...
-
![]()
Figure 5: (a) Photographs of the HACC-rGO/CS films (peeled from the copper plates) with various shapes. (b) P...
-
![]()
Figure 6: CV curves of the bare GCE, the GCE with the deposited chitosan film (chitosan/GCE), and the GCE wit...
-
![]()
Figure 7: (a) DPV of the GCE with the deposited HACC-rGO/CS film in the presence of 1-naphthol with different...
-
- Full Research Paper
- Published 16 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Energy eigenvalues close to zero energy as a function of ΔB. Panels a) and b) are for a square of d...
-
![]()
Figure 2: Energy eigenvalues as a function of
![[Graphic 14]](/bjnano/content/inline/2190-4286-9-110-i18.svg?max-width=637&scale=1.18182)
. Panels a) and b) correspond to the phases in Figure 1d with one (ΔB = 2...
-
![]()
Figure 3: Absorption cross-sections
![[Graphic 15]](/bjnano/content/inline/2190-4286-9-110-i19.svg?max-width=637&scale=1.18182)
, ![[Graphic 16]](/bjnano/content/inline/2190-4286-9-110-i20.svg?max-width=637&scale=1.18182)
and ![[Graphic 17]](/bjnano/content/inline/2190-4286-9-110-i21.svg?max-width=637&scale=1.18182)
defined in the main text. The shown results correspond to the spe...
-
![]()
Figure 4: Absorption cross-sections
![[Graphic 19]](/bjnano/content/inline/2190-4286-9-110-i23.svg?max-width=637&scale=1.18182)
, ![[Graphic 20]](/bjnano/content/inline/2190-4286-9-110-i24.svg?max-width=637&scale=1.18182)
and ![[Graphic 21]](/bjnano/content/inline/2190-4286-9-110-i25.svg?max-width=637&scale=1.18182)
for (a) a square of Lx = Ly = 20 LU), and for (b) a rectangle of L...
-
- Full Research Paper
- Published 16 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Schematic picture of the semiconducting wire (yellow) covered by the superconducting layer (green) ...
-
![]()
Figure 2: Color plot of the critical temperature of the system as a function of the chemical potential μw and...
-
![]()
Figure 3: The critical temperature of the system as a function of the Zeeman field h for different values of ...
-
![]()
Figure 4: Critical temperature of the system as a function of the Zeeman field h for εso = 0.46Tc0, Γs→0 and Γ...
-
-
Supp. Info
- Review
- Published 13 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Methane decomposition equilibrium in the presence of inert gas at different temperatures. Reprinted...
-
![]()
Figure 2: A schematic diagram of the DRM reaction on Ni metal. Adapted from [73].
-
![]()
Figure 3: Schematic diagram of carbon species removal by CO2 over (a) Fe–Ni catalyst [28] and (b) Co–Mo–MgO/MWCNT...
-
![]()
Figure 4: The partial pressure effect of (a) CO2 and (b) CH4 on the rate of CH4 reforming; PCO2 = 90 kPa. Rep...
-
![]()
Figure 5: XPS spectra of O 1s of the catalysts. (NCMZ = Ni–Co/MgO–ZrO2, NMZ = Ni/MgO–ZrO2, CMZ = Co/MgO–ZrO2)...
-
![]()
Figure 6: The reforming rates of DRM over the Ni–Co/Al–Mg-O catalyst affected by the (a) CO2 partial pressure...
-
![]()
Figure 7: The formation rates of CO affected by (a) CH4 partial pressure and (b) CO2 partial pressure at diff...
-
![]()
Figure 8: The formation rates of H2 affected by (a) CH4 partial pressure and (b) CO2 partial pressure at diff...
-
![]()
Figure 9: (a) Schematic illustration of the two synthesis methods for the MgO basic sites formation on SBA-15...
-
![]()
Figure 10: (a) CH4 conversion, (b) CO2 conversion, (c) H2/CO ratio of catalysts with different nickel loadings...
-
![]()
Figure 11: Stability of CH4 conversion over Ni/MgO catalysts with different Ni loadings (5% to 15%) in a DRM r...
-
![]()
Figure 12: Effect of MgO loading on (a) CH4, (b) CO2 conversion and (c) H2/CO molar ratio over various MgO loa...
-
![]()
Figure 13: Conversion of methane (a) and carbon dioxide (b) on N55M11 calcined at different temperatures (■) 4...
-
![]()
Figure 14: The effect of reaction temperature on catalyst performance: (a) CH4 conversion, (b) CO2 conversion,...
-
![]()
Figure 15: Influence of gas hourly space velocity (GHSV) on the catalyst performance of 20 wt % Ni/3 wt % MgO–...
-
- Full Research Paper
- Published 12 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Energy spectra for a) B = 0 and b) B = 4.0 T. Note that the system is gapped at B = 0 but not at B ...
-
![]()
Figure 2: a) Transmission function and b) thermoelectric current for two different magnetic fields. In a), th...
-
![]()
Figure 3: a) Transmission function and b) thermoelectric current calculated in the presence of impurities at B...
-
- Full Research Paper
- Published 11 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Characterizing the degree of reduction of GO sheets reduced using various methods. C 1s XPS spectra...
-
![]()
Figure 2: Characterizing the degree of reduction of GO sheets using EFM imaging and EFS: (a) tapping AFM imag...
-
![]()
Figure 3: Illustrative diagram of EFM imaging and EFS: (a) schematic depiction of EFM, (b) electrostatic forc...
-
- Full Research Paper
- Published 10 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Linear sweep voltammetry under intermittent UV light excitation (Hg lamp 320–380 nm) of intensity 7...
-
![]()
Figure 2: Cyclic voltammograms on an uncoated FTO(A) electrode and one covered by TiO2 films consisting of 10...
-
![]()
Figure 3: Linear sweep voltammetry under intermittent UV light (Hg lamp 320–380 nm; intensity 7.5 mW/cm2). Pr...
-
![]()
Figure 4: Cyclic voltammograms for TiO2 films; precursor: 0.05M TAA, deposition temperature: 450 °C, scan rat...
-
![]()
Figure 5: Top view SEM images of FTO glass substrates, (a) FTO(A) and (b) FTO(B).
-
![]()
Figure 6: Cyclic voltammograms on a FTO(B) substrate covered by TiO2 films of (a) 20 SCs, (b) 50 SCs and (c) ...
-
![]()
Figure 7: Top view SEM images of a) bare FTO(B), b) FTO(B) covered by 20 SCs of 0.2 M TAA, c) FTO(B) covered ...
-
![]()
Figure 8: Cyclic voltammograms of FTO(B) covered by sprayed TiO2 films made of 70 SCs of 0.2 M TAA and of 0.2...
-
-
Supp. Info
- Full Research Paper
- Published 09 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Scanning electron micrographs of the Py antidot arrays with triangular holes of edge length 200 nm,...
-
![]()
Figure 2: (a–f) Experimental time-resolved Kerr rotation data for some specific orientations of the bias magn...
-
![]()
Figure 3: Bias magnetic field dependence of precessional frequencies of different SW modes for (a) Py blanket...
-
![]()
Figure 4: Spin-wave mode profile. (a) Power and (b) phase of S1 for different orientations of the in-plane bi...
-
![]()
Figure 5: Spin-wave mode profile (power and phase) of S2 for different orientations of the in-plane bias fiel...
-
![]()
Figure 6: Magnetization distribution and the contour maps of simulated magnetostatic field distribution of th...
-
-
Supp. Info
- Full Research Paper
- Published 06 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Generalized Maxwell or Wiechert mechanical model diagram representing the relationship between stre...
-
![]()
Figure 2: Numerical simulations corresponding to a parabolic AFM tip tapping on a polyisobutylene surface, de...
-
![]()
Figure 3: Polystyrene thin-film topography images for AM-AFM using the fundamental eigenmode (a), AM-AFM usin...
-
-
Supp. Info
- Full Research Paper
- Published 05 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Structures of (a) P3HT and (b) PCBM.
-
![]()
Figure 2: UV–vis absorbance spectra of P3HT, PCBM and P3HT:PCBM (1:1) thin films.
-
![]()
Figure 3: Thickness d and tanΨ as functions of the temperature for (a) P3HT, (b) PCBM and (c) P3HT:PCBM (1:1)...
-
![]()
Figure 4: Δ at 280 nm as a function of temperature for P3HT:PCBM blend films with different polymer contents:...
-
![]()
Figure 5: DSC plots with a heating rate of 20 °C/min for P3HT, PCBM and P3HT:PCBM (1:1), recorded with powder...
-
![]()
Figure 6: Phase diagram of P3HT:PCBM blends films. Symbols marked as TgP3HT, TgBLEND and TgPCBM denote the gl...
-
- Full Research Paper
- Published 05 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Force versus separation curve for the 2 wt % suspension. Grey open circles show a single force curv...
-
![]()
Figure 2: Combined force data of the 9 wt % suspension (black dots) together with fits based on Equation 1 from differe...
-
![]()
Figure 3: Combined force data of the 9 wt % suspension (black dots) together with the fit parameters A (circl...
-
![]()
Figure 4: Combined force data of the 9 wt % suspension (black dots) together with fit based on Equation 1 made from 200...
-
![]()
Figure 5: Combined force data of the 9 wt % suspension (black dots) together with the fit based on Equation 2 made from...
-
![]()
Figure 6: Combined force data of the 9 wt % suspension (black dots) together with the fit parameters over the...
-
![]()
Figure 7: Combined force data of the 9 wt % suspension (black dots) together with the fit parameters over the...
-
![]()
Figure 8: Log–log scale of wavelength λ as a function of the silica nanoparticle concentration and the respec...
-
![]()
Figure 9: Decay length ξ1 (triangles) together with ξ2 (pentagons) in nm as a function of the suspension conc...
-
![]()
Figure 10: Amplitude A (circles) as well as parameter B (diamonds) in pN as a function of the suspension conce...
-
![]()
Figure 11: B·ξ2 in aJ as a function of the suspension concentration in wt % together with a linear trend. Two ...
-
-
Supp. Info
- Full Research Paper
- Published 04 Apr 2018
-
PDF -
Album-
![]()
Figure 1: The experimental setup of the scanning confocal microscope used for investigating TiO2 defects.
-
![]()
Figure 2: Representative 100 × 100 μm2 confocal scans of TiO2 morphologies. E-beam deposited thin films: (a) ...
-
![]()
Figure 3: 10 × 10 μm2 confocal scans of two single-photon emitters (a) defect D1 and (b) defect D2 found on t...
-
![]()
Figure 4: Characterisation results of defect D1, shown in Figure 3a, found in the a-450 °C-TiO2 sample. (a) Normalised...
-
![]()
Figure 5: Characterisation results of defect D2. (a) The excited-state (RLT) and non-radiative (NRLT) lifetim...
-
![]()
Figure 6: Characterisation results of a defect found in the sample of TiO2 anatase nanopowder and IPA. (a) 10...
-
- Full Research Paper
- Published 04 Apr 2018
-
PDF -
Album-
![]()
Figure 1: A schematic of the measured and simulated QD system. The dimensions of the simulated structure are ...
-
![]()
Figure 2: The atomistic grid of the simulated QD showing only cations (Al,Ga,In) to emphasize the randomness ...
-
![]()
Figure 3: Bond lengths and bond angle for three neighboring atoms m, n, and k.
-
![]()
Figure 4: An InAs/GaAs quantum well of thickness 3 nm used for the optimization of the anharmonic strain mode...
-
![]()
Figure 5: The simulated and the measured absorption spectrum of the QD system. The quantum dot is sample D fr...
-
![]()
Figure 6: The magnitude square of the wave functions of the electron and hole states. Only the first eight el...
-
![]()
Figure 7: The conduction and valence band edges (solid lines) along a line through the middle of the quantum ...
-
![]()
Figure 8: The in-plane polarized absorption spectrum calculated for (A) different diameters and (B) different...
-
![]()
Figure 9: Hydrostatic εH and biaxial εB strain with different dimensions along a line through the middle of t...
-
![]()
Figure 10: Experimental and simulation results of the optical transition of the QD system reported in [9]. Increa...
-
![]()
Figure 11: Hydrostatic and biaxial strain with different mole fractions of In along a line passing through the...
-
- Review
- Published 03 Apr 2018
-
PDF -
Album-
![]()
Figure 1: Nanomaterials with different morphologies: (A) nonporous Pd NPs (0D) [9,10], copyright Zhang et al.; lice...
-
![]()
Figure 2: FESEM of dust particle samples collected (a) during and (b) after the dust storm episodes on March ...
-
![]()
Figure 3: (a) SEM image of flaming smoke collected during a Madikwe Game Reserve fire in South Africa on Augu...
-
![]()
Figure 4: (A) Negatively stained rotavirus with complete (long arrow) and empty (short arrow) particles in sw...
-
![]()
Figure 5: Nanoparticles synthesized intracellularly in algae and fungi. (A) TEM micrograph of R. mucilaginosa...
-
![]()
Figure 6: Photographs and the scanning electron microscope images of various bio-prototypes bearing superhydr...
-
![]()
Figure 7: (A) Photograph of peacock feathers showing various colors and patterns. (B) Cross-sectional SEM ima...
-
![]()
Figure 8: The macro- and microstructure of bone and its components with nanostructured materials employed in ...
-
![]()
Figure 9: Electron microscope images show how NPs can penetrate and relocate to various sites inside a phagoc...
-
- Full Research Paper
- Published 03 Apr 2018
-
PDF -
Album-
![]()
Figure 1: (a) Cosine of 18 times the magnetic phase shift recorded using EH from Co NWs deposited at electron...
-
![]()
Figure 2: (a) In-focus bright-field TEM image of a Co NW. (b) L-TEM underfocus image of the NW, exhibiting a ...
-
![]()
Figure 3: L-TEM images of square rings, showing the magnetization directions under different magnetic fields B...
-
![]()
Figure 4: (a) AFM image of a square ring. (b) Height profile corresponding to the red dashed line in (a). (c)...
-
- Letter
- Published 29 Mar 2018
-
PDF -
Album-
![]()
Figure 1: Photoconductivity kinetics Δσ/σ0 in Hg1−xCdxTe films with x = 0.13 (the upper panel) and x = 0.17 (...
-
![]()
Figure 2: Dependence of the absolute value of the peak photoresponse amplitude |Δσ/σ0|peak (σ0 is the conduct...
-
![]()
Figure 3: Sketch of the smooth heteroboundary between the Hg1−xCdxTe active layer (with the inverted band str...
-
- Full Research Paper
- Published 29 Mar 2018
-
PDF -
Album-
![]()
Figure 1: SEM overview images in back scattering electron (BSE) contrast mode for the as-prepared samples of ...
-
![]()
Figure 2: SEM overview images in BSE contrast of the annealed samples of Fe50Co50@CNT (at 600 °C for 48 h) pr...
-
![]()
Figure 3: TEM bright field images for the a) as-prepared and b) annealed samples of Fe50Co50@CNT prepared by ...
-
![]()
Figure 4: Histograms representing the distribution of the inner diameter (nm) of the CNTs and particle diamet...
-
![]()
Figure 5: XRD diffraction patterns for the as-prepared and annealed samples of Fe50Co50@CNT prepared by the a...
-
![]()
Figure 6: Relative sample mass loss for a sample prepared by the first (i.e., solution) approach (black) and ...
-
![]()
Figure 7: Hysteresis curves measured at a) 300 K and c) 5 K for the annealed and the as-prepared Fe50Co50@CNT...
-
-
Supp. Info
- Full Research Paper
- Published 28 Mar 2018
-
PDF -
Album-
![]()
Figure 1: Comparison between different calculations of the band structure of monolayer antimonene as obtained...
-
![]()
Figure 2: Radial probability density of two selected elements of the AE and small-core basis sets used in the...
-
![]()
Figure 3: Comparison between different calculations of the band structure of monolayer antimonene as obtained...
-
![]()
Figure 4: Comparison between different calculations of the band structure of monolayer antimonene including S...
-
![]()
Figure 5: Band structure of 9 layers, ABC stacking Sb(111) films as obtained from small core pseudopotential ...
-
![]()
Figure 6: Band structure of a Bi(111) monolayer, obtained from VASP (dashed black) and small core pseudopoten...
-
- Full Research Paper
- Published 27 Mar 2018
-
PDF -
Album-
![]()
Figure 1: (a) Diagrams showing the physical models of Fe and Ni used in the simulations. (b) Diagram showing ...
-
![]()
Figure 2: Force–distance curve of Ni under two times of cyclic loading, where the tension and compression dis...
-
![]()
Figure 3: Crack growth and expansion diagrams of Ni under the first cyclic loading at different moving distan...
-
![]()
Figure 4: Crack growth and expansion diagrams of Ni during the second cyclic loading at different moving dist...
-
![]()
Figure 5: Force–distance curve of Ni under ten times of cyclic loading, where the first tension distance of t...
-
![]()
Figure 6: Crack growth and expansion diagrams of Ni corresponding to the observation positon a–f annotated in ...
-
![]()
Figure 7: Force–distance curve of Fe under two times of cyclic loading, where the tension and compression dis...
-
![]()
Figure 8: Crack growth and expansion diagrams of Fe under the first cyclic loading at different moving distan...
-
![]()
Figure 9: Crack growth and expansion diagrams of Fe under the second cyclic loading at different moving dista...
-
![]()
Figure 10: Force–distance curve of Fe under ten times of cyclic loading, where the first tension distance of t...
-
![]()
Figure 11: Crack growth and expansion diagrams of Fe corresponding to the observation positons a–f annotated i...
-
![]()
Figure 12: Comparison between the growth of crack length for Ni and Fe under ten times of cyclic loading.
-
![]()
Figure 13: Force–distance curve of Ni under ten times of cyclic loading, where the first shear distance of the...
-
![]()
Figure 14: Crack growth and expansion diagrams of Ni corresponding to the observation positions a–f in Figure 13.
-
![]()
Figure 15: Force–distance curve of Fe under ten times of cyclic loading, where the first shear distance of the...
-
![]()
Figure 16: Crack growth and expansion diagrams of Fe corresponding to the observation positons a–f annotated i...
-
![]()
Figure 17: Force–distance curve of Ni along orientation I (black dashed line) and orientation II (red line) un...
-
![]()
Figure 18: Crack growth and expansion diagrams of Ni along orientation II corresponding to the observation pos...
-
![]()
Figure 19: Force–distance curves of Fe along the orientation I (black dashed line) and orientation II (red lin...
-
![]()
Figure 20: Crack growth and expansion diagrams of Fe along the orientation II corresponding to the observation...
-
