Disorder in H⁺-irradiated HOPG: effect of impinging energy and dose on Raman D-band splitting and surface topography

Lisandro Venosta,
Noelia Bajales,
Sergio Suárez and
Paula G. Bercoff

Full Research Paper
Published 19 Oct 2018

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1. Figure 1: Raman spectra of irradiated HOPG (LD-LE, LD-HE, HD-LE and HD-HE). Pristine HOPG is shown for compar...
  
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2. Figure 2: Deconvolution of a) D band and b) 2D band. The dotted vertical lines are drawn as a guide to the ey...
  
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3. Figure 3: Linear dependence of the (total) I_D/I_D′ ratio and the (separate) contributions of I_D1/I_D′ and I_D2/I...
  
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4. Figure 4: a) Hysteresis loops of pristine HOPG and irradiated samples with low (LD) and high (HD) H⁺ doses, i...
  
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5. Figure 5: AFM images and height profiles of (a, d) pristine HOPG, (b, e) HOPG irradiated at low dose and low ...
  
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6. Figure 6: Statistical analysis of superficial defect sizes obtained from AFM images for a) low dose (LD-LE) a...
  
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Beilstein J. Nanotechnol. 2018, 9, 2708–2717, doi:10.3762/bjnano.9.253

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Optimization of Mo/Cr bilayer back contacts for thin-film solar cells

Nima Khoshsirat,
Fawad Ali,
Vincent Tiing Tiong,
Mojtaba Amjadipour,
Hongxia Wang,
Mahnaz Shafiei and
Nunzio Motta

Full Research Paper
Published 18 Oct 2018

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1. Figure 1: Samples after adhesion test. (a–c) Mo/SLG; (d–f) Mo/Cr/SLG. (a, d) 100 W, 10 mTorr, (b, e) 150 W, 5...
  
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2. Figure 2: Sheet resistivity of Mo/Cr films prepared at different values of sputtering power and pressure.
  
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3. Figure 3: Surface SEM images of Mo/Cr films prepared at sputtering power and pressure values of (a) 100 W, 3 ...
  
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4. Figure 4: Average surface roughness of Mo/Cr films prepared at different sputtering powers and pressures.
  
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5. Figure 5: X-ray diffraction peaks of Mo/Cr films prepared using different values of sputtering power and pres...
  
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6. Figure 6: Optical reflectance of Mo/Cr films prepared using different values of sputtering power and pressure....
  
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7. Figure 7: XPS depth profile of the Mo/Cr films deposited at 200 W and 3 mTorr.
  
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8. Figure 8: J–V characteristics of the CZTS cell with Mo/Cr bilayer back contact.
  
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Beilstein J. Nanotechnol. 2018, 9, 2700–2707, doi:10.3762/bjnano.9.252

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Size-selected Fe₃O₄–Au hybrid nanoparticles for improved magnetism-based theranostics

Maria V. Efremova,
Yulia A. Nalench,
Eirini Myrovali,
Anastasiia S. Garanina,
Ivan S. Grebennikov,
Polina K. Gifer,
Maxim A. Abakumov,
Marina Spasova,
Makis Angelakeris,
Alexander G. Savchenko,
Michael Farle,
Natalia L. Klyachko,
Alexander G. Majouga and
Ulf Wiedwald

Full Research Paper
Published 16 Oct 2018

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1. Figure 1: Bright-field TEM images of size-selected magnetite–gold NPs with in situ synthesized Au seeds: A) M...
  
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2. Figure 2: XRD patterns of Fe₃O₄–Au NPs. Panels are sorted by magnetic NP size from bottom to top – samples MN...
  
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3. Figure 3: HRTEM and corresponding FTT images of size-selected magnetite–gold NPs: MNP-15 (A, C) and MNP-25 (B...
  
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4. Figure 4: Magnetic properties of Fe₃O₄–Au hybrid NPs. ZFC/FC curves at B = 5 mT (A). T_V indicates the Verwey ...
  
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5. Figure 5: Inverse of the MRI proton T₂-relaxation time as a function of iron concentration for MNP-6, MNP-15,...
  
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6. Figure 6: MPH experiments (765 kHz, 30 mT). The heating curves of MNP-6 and MNP-25 (3.6 mg·mL⁻¹ Fe) in water ...
  
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7. Figure 7: Cell viability study (MTS assay) of 4T1 cells after 15 and 30 min incubation with NPs during AMF ex...
  
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Beilstein J. Nanotechnol. 2018, 9, 2684–2699, doi:10.3762/bjnano.9.251

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Silencing the second harmonic generation from plasmonic nanodimers: A comprehensive discussion

Jérémy Butet,
Gabriel D. Bernasconi and
Olivier J. F. Martin

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Published 15 Oct 2018

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1. Figure 1: (a) Example of one mesh used for the simulations. The nanorod overall length and diameter are 85 nm...
  
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2. Figure 2: (a) Enhancement of the fundamental intensity evaluated at the nanorod extremities (2.5 nm away from...
  
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3. Figure 3: Maximal second harmonic generation (SHG) as a function of the gap between the nanorods. The maximal...
  
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4. Figure 4: Normalized near-field distributions of the second harmonic electric field intensity close to the go...
  
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5. Figure 5: Far-field second harmonic intensity for the entire surface nonlinear polarization (100%) and for pa...
  
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6. Figure 6: (a) Mesh used for the dimers with defects. In this example, the gap is 20 nm. Far-field second harm...
  
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7. Figure 7: (a) Example of one mesh used for the simulations for the dimers with rectangular arms. The nanopart...
  
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8. Figure 8: (a) Enhancement of the fundamental intensity evaluated at the nanorod extremities (2.5 nm away from...
  
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9. Figure 9: Far-field second harmonic intensity for the entire surface nonlinear polarization (100%) and for pa...
  
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Beilstein J. Nanotechnol. 2018, 9, 2674–2683, doi:10.3762/bjnano.9.250

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Two-dimensional semiconductors pave the way towards dopant-based quantum computing

José Carlos Abadillo-Uriel,
Belita Koiller and
María José Calderón

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Published 12 Oct 2018

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1. Figure 1: Schematic representation of the electronic distributions around two donors (represented in red) in ...
  
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2. Figure 2: (a) Bohr radii and energy for one electron bound to a donor pair as a function of R. For R = 2a^*, ...
  
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3. Figure 3: Minimum dielectric constant that guarantees the existence of bound states and the validity of EMA f...
  
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Beilstein J. Nanotechnol. 2018, 9, 2668–2673, doi:10.3762/bjnano.9.249

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Silicene, germanene and other group IV 2D materials

Patrick Vogt

Editorial
Published 10 Oct 2018

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1. Figure 1: Illustration of the increasing buckling of different elemental 2D materials.
  
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Beilstein J. Nanotechnol. 2018, 9, 2665–2667, doi:10.3762/bjnano.9.248

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Polarization-dependent strong coupling between silver nanorods and photochromic molecules

Gwénaëlle Lamri,
Alessandro Veltri,
Jean Aubard,
Pierre-Michel Adam,
Nordin Felidj and
Anne-Laure Baudrion

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Published 08 Oct 2018

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1. Figure 1: (a) SEM image of silver nanorods. The 0° and 90° polarization orientations correspond to the nanoro...
  
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2. Figure 2: Extinction spectra of the silver nanorod arrays covered with photochromic molecules before (in SPY)...
  
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3. Figure 3: (a) Experimental spectral evolution of the transverse (90°) plasmonic peak as a function of the rod...
  
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4. Figure 4: (a) Extinction spectrum (grey curve) recorded with a 70 nm wide and 90 nm long nanorod array covere...
  
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Beilstein J. Nanotechnol. 2018, 9, 2657–2664, doi:10.3762/bjnano.9.247

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Nanoantenna structures for the detection of phonons in nanocrystals

Alexander G. Milekhin,
Sergei A. Kuznetsov,
Ilya A. Milekhin,
Larisa L. Sveshnikova,
Tatyana A. Duda,
Ekaterina E. Rodyakina,
Alexander V. Latyshev,
Volodymyr M. Dzhagan and
Dietrich R. T. Zahn

Full Research Paper
Published 05 Oct 2018

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1. Figure 1: Representative SEM images of a) and b) linear and c) and d) H-shaped nanoantenna arrays with differ...
  
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2. Figure 2: a) Typical IR transmission spectrum for the array of nanoantennas with a length of 1800 nm. The low...
  
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3. Figure 3: Optimized nanoantenna length L vs the transverse crossarm length L_H for H-shaped nanoantennas with ...
  
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4. Figure 4: Distribution of the normalized LSPR electric field magnitude on top of the Si surface underlying th...
  
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5. Figure 5: IR transmission spectra of the array of a) nanoantennas and b) microantennas measured at different ...
  
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6. Figure 6: a) Evaluating the spectral behavior of the dipole radiation from a unit cell of the Si-backed array...
  
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7. Figure 7: SEM images of the nanoantenna edges for a) linear and b) H-shaped nanoantennas taken after depositi...
  
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8. Figure 8: IR transmission spectra of the linear nanoantenna arrays before nanocrystal (NC) deposition (black ...
  
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Beilstein J. Nanotechnol. 2018, 9, 2646–2656, doi:10.3762/bjnano.9.246

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Nanostructured liquid crystal systems and applications

Alexei R. Khokhlov and
Alexander V. Emelyanenko

Editorial
Published 05 Oct 2018

Beilstein J. Nanotechnol. 2018, 9, 2644–2645, doi:10.3762/bjnano.9.245

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Impact of the anodization time on the photocatalytic activity of TiO₂ nanotubes

Jesús A. Díaz-Real,
Geyla C. Dubed-Bandomo,
Juan Galindo-de-la-Rosa,
Luis G. Arriaga,
Janet Ledesma-García and
Nicolas Alonso-Vante

Full Research Paper
Published 04 Oct 2018

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1. Figure 1: SEM images, a) top and b) cross section, of TNTs for each of the anodization times (t_a): c) 0.5 h, ...
  
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2. Figure 2: High-resolution XPS spectra for Ti 2p, O 1s, F 1s and N 1s obtained for the TNTs after each t_a.
  
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3. Figure 3: X-ray diffraction patterns of TNT grown at different t_a.
  
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4. Figure 4: Raman spectra for TNT grown at different t_a. Laser intensity: 2.5 mW/cm².
  
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5. Figure 5: (a) Cyclic voltammograms (CV) at v = 50 mV/s; and (b) linear-sweep voltammograms (LSV) at v = 5 mV/...
  
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6. Figure 6: Extracted photo-current density, j_ph, from potentiodynamic curves for the TNTs grown at different t_a...
  
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7. Figure 7: (a) Incident photon-to-current (IPCE) plot for each TNT. (b) Tauc plots for a direct electronic tra...
  
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8. Figure 8: a) Mott–Schottky plots recorded at f = 400 Hz in 0.5 M H₂SO₄. The electrode potential range was fro...
  
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9. Figure 9: a) Schematics of the experimental setup used for the PEC degradation of MB. b) UV–vis spectra for t...
  
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Beilstein J. Nanotechnol. 2018, 9, 2628–2643, doi:10.3762/bjnano.9.244

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Characterization of the microscopic tribological properties of sandfish (Scincus scincus) scales by atomic force microscopy

Weibin Wu,
Christian Lutz,
Simon Mersch,
Richard Thelen,
Christian Greiner,
Guillaume Gomard and
Hendrik Hölscher

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Published 02 Oct 2018

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1. Figure 1: (a) Photograph of a sandfish (S. scincus) in its natural habitat (copyright Gerrit Jan Verspui). (b...
  
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2. Figure 2: SEM images of some probes used in this study. (a) Sharp tip of a conventional AFM cantilever made f...
  
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3. Figure 3: Structure of the analysed S. scincus scales. (a) The topography of a dorsal scale measured by atomi...
  
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4. Figure 4: (a) Typical force–distance curves obtained with sand probe, spherical glass probe and sharp silicon...
  
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5. Figure 5: Direct comparison of the adhesion force measured with a sand probe on the scales of four species (P...
  
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6. Figure 6: (a) Frictional force as a function of the normal load measured with a sharp silicon tip on a dorsal...
  
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7. Figure 7: (a) Wear experiments recorded on five different materials with hard cantilevers (spring constant of...
  
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8. Figure 8: Comparison of the friction coefficients as measured by AFM and microtribometry in a sphere-on-plate...
  
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Beilstein J. Nanotechnol. 2018, 9, 2618–2627, doi:10.3762/bjnano.9.243

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Enhancement of X-ray emission from nanocolloidal gold suspensions under double-pulse excitation

Wei-Hung Hsu,
Frances Camille P. Masim,
Armandas Balčytis,
Hsin-Hui Huang,
Tetsu Yonezawa,
Aleksandr A. Kuchmizhak,
Saulius Juodkazis and
Koji Hatanaka

Full Research Paper
Published 01 Oct 2018

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1. Figure 1: (a) Schematics of experiment showing polarizations of the pre-pulse E₁ and the main pulse E₂ in the...
  
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2. Figure 2: X-ray intensities from (a) a water film and (b) a film of a colloidal suspension of gold nanosphere...
  
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3. Figure 3: X-ray intensity at different positions of the water film (a) and the gold nanosphere colloidal solu...
  
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4. Figure 4: Position of X-ray maximum generation (a) and its intensity (b) for distilled water films at short e...
  
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5. Figure 5: FDTD simulations of light-field enhancement under the conditions of the experiment: angle of incide...
  
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Beilstein J. Nanotechnol. 2018, 9, 2609–2617, doi:10.3762/bjnano.9.242

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Au–Si plasmonic platforms: synthesis, structure and FDTD simulations

Anna Gapska,
Marcin Łapiński,
Paweł Syty,
Wojciech Sadowski,
Józef E. Sienkiewicz and
Barbara Kościelska

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Published 28 Sep 2018

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1. Figure 1: Scheme of the formation of the gold nanoislands.
  
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2. Figure 2: SEM images of 2.8 nm Au films on a Si(111) substrate: a) as prepared, annealed at b) 150 °C, c) 200...
  
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3. Figure 3: SEM images of 2.8 nm Au films on a Si(111) substrate annealed at a) 450 °C, b) 550 °C, c) 600 °C fo...
  
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4. Figure 4: SEM images of Au films of different thicknesses on a Si(111) substrate annealed at 550 °C for 15 mi...
  
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5. Figure 5: a) Number of nanoparticles and b) average diameter of nanoparticles as function of the Au film thic...
  
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6. Figure 6: Left: AFM image of a 2.8 nm Au film on a Si(111) substrate annealed at 550 °C for 15 min; right: cr...
  
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7. Figure 7: XRD result of a 2.8 nm Au film annealed at 550 °C for 15 min and an as-prepared 2.8 nm Au film on S...
  
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8. Figure 8: XPS (Au region) results for the 2.8 nm Au thin film on a Si(111) substrate annealed at 550 °C for 1...
  
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9. Figure 9: XPS result (Si region) for the 2.8 nm Au film on a Si(111) substrate annealed at 550 °C for 15 min.
  
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10. Figure 10: Absorbance spectra recorded for a 2.8 nm Au film on a Si(111) substrate annealed at 550 °C for 15 m...
  
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11. Figure 11: SEM image of the gold nanoislands on the silicon substrate (sample 2.8 nm Au film on Si(111) substr...
  
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12. Figure 12: Setup for the FDTD and FDTD/DFT simulations. Left: view from the bottom, zx-plane; yellow rectangle...
  
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13. Figure 13: Calculated intensity distribution of the electromagnetic field with unpolarized incident light of a...
  
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14. Figure 14: Calculated amplitudes of the components of the electromagnetic field with unpolarized incident ligh...
  
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15. Figure 15: Calculated absorbance (as log(I_o/I_r), where I_o is an incident flux, and I_r – reflected flux), as th...
  
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Beilstein J. Nanotechnol. 2018, 9, 2599–2608, doi:10.3762/bjnano.9.241

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Pattern generation for direct-write three-dimensional nanoscale structures via focused electron beam induced deposition

Lukas Keller and
Michael Huth

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Published 27 Sep 2018

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1. Figure 1: Block-flow diagram of the environment of the pattern generator program using input from a geometry ...
  
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2. Figure 2: Illustration of the three dimensional pitch Π_3D, projected in the x–z-plane: In every frame each ac...
  
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3. Figure 3: Visualization of the height-dependent deposition rate: The blue circles correspond to vertices defi...
  
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4. Figure 4: Schematic overview of the angle-sorted proximity avoiding algorithm (asPAA). a: In order to minimiz...
  
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5. Figure 5: Schematic overview of the best permutation proximity avoiding algorithm (bpPAA). The algorithm gene...
  
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6. Figure 6: Calibration of deposition speed parameters x_F und z_F. Shown is one deposition series from 52° tilte...
  
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7. Figure 7: Angle-test structure consisting of several elements. Each element has a vertical pillar and a tilte...
  
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8. Figure 8: Avoiding of proximity effects: A and B are 2 × 2 arrays of cubes resting on a short pillar. They ar...
  
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9. Figure 9: Comparison of the angle-sorted proximity avoiding algorithm (asPAA) and the best permutation PAA (b...
  
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10. Figure 10: Height correction: Both left images are taken from a 52° tilted view. (A) is deposited without heig...
  
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11. Figure 11: Array of trees, each consisting of a root and three branches. The roots of the trees of the second ...
  
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12. Figure 12: Buckyball structure in top and side view (52° tilted). Precursor: Me₃CpMePt(IV), normal mode.
  
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13. Figure 13: 2 × 2 array of nanotrees consisting of a root and branches deposited with the CoFe precursor and a ...
  
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14. Figure 14: Working principle of the simple shadowing algorithm. A plane is defined parallel to the opening of ...
  
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15. Figure 15: In order to investigate the shape of edge tips with different edge inclination, deposits like shown...
  
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Beilstein J. Nanotechnol. 2018, 9, 2581–2598, doi:10.3762/bjnano.9.240

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Exploring the photoleakage current and photoinduced negative bias instability in amorphous InGaZnO thin-film transistors with various active layer thicknesses

Dapeng Wang and
Mamoru Furuta

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Published 26 Sep 2018

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1. Figure 1: (a) Schematic cross-sectional view and (b) the initial transfer characteristics of a-IGZO TFTs with...
  
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2. Figure 2: Variation in the transfer characteristics of a-IGZO TFTs with (a) T_IGZO = 25, (b) 45, (c) 75, and (...
  
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3. Figure 3: Variation in the transfer characteristics in the forward measurement for a-IGZO TFTs with (a) T_IGZO...
  
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4. Figure 4: (a) Variation in V_th of the transfer curves of a-IGZO TFTs with various T_IGZO in the reverse measur...
  
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5. Figure 5: C−V curves before and after the NBIS duration of 10⁴ s with (a) T_IGZO = 25, (b) 45, (c) 75, and (d)...
  
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6. Figure 6: Schematic diagram of NBIS-induced degradation mechanism in a-IGZO TFTs with (a) T_IGZO < 45 and (b) ...
  
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Beilstein J. Nanotechnol. 2018, 9, 2573–2580, doi:10.3762/bjnano.9.239

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Friction reduction through biologically inspired scale-like laser surface textures

Johannes Schneider,
Vergil Djamiykov and
Christian Greiner

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Published 26 Sep 2018

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1. Figure 1: Scanning electron microscopy and white light profilometry images of laser-textured bearing steel (1...
  
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2. Figure 2: Stribeck curve-like pin-on-disc experiments for a variation in sliding speed from 20 to 170 mm/s fo...
  
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3. Figure 3: Stribeck curve-like pin-on-disc experiments for a variation in sliding speed from 20 to 170 mm/s fo...
  
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4. Figure 4: Stribeck curve-like pin-on-disc experiments for a variation in sliding speed from 20 to 170 mm/s fo...
  
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5. Figure 5: Comparison of the average friction coefﬁcient for the last 250 m of unlubricated tribological exper...
  
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Beilstein J. Nanotechnol. 2018, 9, 2561–2572, doi:10.3762/bjnano.9.238

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Effective sensor properties and sensitivity considerations of a dynamic co-resonantly coupled cantilever sensor

Julia Körner

Full Research Paper
Published 25 Sep 2018

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1. Figure 1: (a) Scanning electron microscopy image of a sensor realization consisting of a silicon microcantile...
  
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2. Figure 2: Calculated microcantilever amplitude response curve of the co-resonantly coupled system based on th...
  
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3. Figure 3: (a) Resonance amplitudes of both resonance peaks of the coupled system calculated for the microcant...
  
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4. Figure 4: This diagram represents the necessary calculation steps to determine the effective spring constant ...
  
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5. Figure 5: Effective spring constants for both resonance peaks of the coupled system in dependence on the eige...
  
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6. Figure 6: Effective quality factor for both resonance peaks of the coupled system in dependence on the eigenf...
  
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7. Figure 7: Qualitative behaviour of the effective quality factor for both resonance peaks of the coupled syste...
  
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Beilstein J. Nanotechnol. 2018, 9, 2546–2560, doi:10.3762/bjnano.9.237

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Cytotoxicity of doxorubicin-conjugated poly[N-(2-hydroxypropyl)methacrylamide]-modified γ-Fe₂O₃ nanoparticles towards human tumor cells

Zdeněk Plichta,
Yulia Kozak,
Rostyslav Panchuk,
Viktoria Sokolova,
Matthias Epple,
Lesya Kobylinska,
Pavla Jendelová and
Daniel Horák

Full Research Paper
Published 25 Sep 2018

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1. Figure 1: (a) ¹H NMR, (b) gas chromatogram, and (c) FTIR spectrum of 2-(N-methylmethacrylamido)acetate (MMAA)....
  
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2. Figure 2: Scheme of RAFT copolymerization of N-(2-hydroxypropyl)methacrylamide (HPMA) with methyl 2-(N-methyl...
  
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3. Figure 3: FTIR spectrum of poly[N-(2-hydroxypropyl)methacrylamide-co-2-(N-methylmethacrylamido)acetate] [P(HP...
  
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4. Figure 4: TEM micrographs of (a) γ-Fe₂O₃ and (b) γ-Fe₂O₃@PHPMA nanoparticles.
  
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5. Figure 5: Schematic illustration of the interaction between PHMPA and a maghemite nanoparticle followed by th...
  
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6. Figure 6: Comparison of short-term cytotoxicity (24 h of incubation) of γ-Fe₂O₃@PHPMA (NP), Dox, and γ-Fe₂O₃@...
  
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7. Figure 7: Comparison of short- and long-term cytotoxicity of γ-Fe₂O₃@PHPMA (NP), Dox, and γ-Fe₂O₃@P(HPMA-MMAA...
  
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8. Figure 8: Comparison of short- and long-term cytotoxicity of γ-Fe₂O₃@PHPMA (NP), Dox, and γ-Fe₂O₃@P(HPMA-MMAA...
  
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9. Figure 9: Fluorescence micrographs of (a) primary hMSCs, (b) tumor MG-63, and (c) HeLa cells after 48 h of in...
  
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10. Figure 10: Cytomorphological determination of chromatin hypercondensation in DAPI-stained murine B16 melanoma ...
  
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11. Figure 11: Live/dead staining of (a, c, e, g) human osteosarcoma MG-63 cells and (b, d, f, h) human cervix car...
  
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Beilstein J. Nanotechnol. 2018, 9, 2533–2545, doi:10.3762/bjnano.9.236

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Improved catalytic combustion of methane using CuO nanobelts with predominantly (001) surfaces

Qingquan Kong,
Yichun Yin,
Bing Xue,
Yonggang Jin,
Wei Feng,
Zhi-Gang Chen,
Shi Su and
Chenghua Sun

Full Research Paper
Published 24 Sep 2018

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1. Figure 1: Computational screening. (a) Models for six low-index surfaces (unrelaxed); (b) Calculated values o...
  
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2. Figure 2: CuO catalyst characterization. (a,b) TEM images of CuO NWs; (c) TEM image of CuO NBs (inset is the ...
  
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3. Figure 3: CH₄ conversion against the temperature. (a) Heating profile (T_max = 850 °C) for NBs, NWs and NPs, w...
  
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4. Figure 4: CH₄ oxidation mechanism by computational calculations. (a) Clean (001); (b) CH₄ physical adsorption...
  
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5. Figure 5: Energy profile for CH₄ oxidation. The geometries are shown in Figure 4.
  
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Beilstein J. Nanotechnol. 2018, 9, 2526–2532, doi:10.3762/bjnano.9.235

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Non-agglomerated silicon–organic nanoparticles and their nanocomplexes with oligonucleotides: synthesis and properties

Asya S. Levina,
Marina N. Repkova,
Nadezhda V. Shikina,
Zinfer R. Ismagilov,
Svetlana A. Yashnik,
Dmitrii V. Semenov,
Yulia I. Savinovskaya,
Natalia A. Mazurkova,
Inna A. Pyshnaya and
Valentina F. Zarytova

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Published 21 Sep 2018

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1. Figure 1: (a) Evaluation of molar ratio of the amino groups in the nanoparticles to the phosphate groups, NH₂...
  
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2. Figure 2: IR (a) and UV (b) spectra of Si–NH₂.
  
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3. Figure 3: TEM images of Si–NH₂ (a) nanoparticles and Si–NH₂·ODN(1) nanocomplexes (b).
  
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4. Figure 4: (a) 3D and (b) 2D AFM images of the Si–NH₂·ODN(1) nanocomplex and (c) a suface profile along the li...
  
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5. Figure 5: Fluorescence microscopy images of A549 human lung adenocarcinoma cells after their incubation with ...
  
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6. Figure 6: Virus titer (log TCID₅₀/mL) of A/chicken/Kurgan/05/2005 virus (H5N1) in the presence of the samples...
  
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Beilstein J. Nanotechnol. 2018, 9, 2516–2525, doi:10.3762/bjnano.9.234

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Enhanced antineoplastic/therapeutic efficacy using 5-fluorouracil-loaded calcium phosphate nanoparticles

Shanid Mohiyuddin,
Saba Naqvi and
Gopinath Packirisamy

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Published 20 Sep 2018

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1. Figure 1: (A) Schematic representation for the preparation of CaP@5-FU NPs. (B) The UV–visible spectrum of Ca...
  
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2. Figure 2: (A) The hydrodynamic diameter and (B) zeta potential of CaP@5-FU NPs in PBS buffer. (C) The FTIR sp...
  
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3. Figure 3: The X-ray diffraction pattern of (A) CaP NPs and (B) CaP@5-FU NPs. (C) TEM and (D) FE-SEM micrograp...
  
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4. Figure 4: Analysis of cell viability by MTT assay for (A) NIH 3T3, (B) A549 and (C) HCT-15 cells upon CaP@5-F...
  
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5. Figure 5: Fluorescence microscopy images of (A) AO/EB stained A549 and HCT-15 cells after 0.5 IC₅₀ and IC₅₀ w...
  
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6. Figure 6: FE-SEM micrograph of untreated control cells A549 and HCT-15 along with CaP@5-FU treated cells at IC...
  
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7. Figure 7: Flow cytometric analysis of (A) CellRox deep red for ROS quantification and intensity of propidium ...
  
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8. Figure 8: (A) Gene expression studies of proapoptotic and antiapoptotic genes in untreated and CaP@5-FU NP-tr...
  
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Beilstein J. Nanotechnol. 2018, 9, 2499–2515, doi:10.3762/bjnano.9.233

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Nanocellulose: Recent advances and its prospects in environmental remediation

Katrina Pui Yee Shak,
Yean Ling Pang and
Shee Keat Mah

Review
Published 19 Sep 2018

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1. Figure 1: Size chart of nanocellulose based on material length (with microscopic images of various nanocellul...
  
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2. Figure 2: The structures of (a) cellulose nanofibers (CNFs) and (b) cellulose nanocrystals (CNCs) produced fr...
  
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3. Figure 3: Resultant chemical structures of nanocellulose prepared via (a) mechanical refining, enzymatic hydr...
  
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4. Figure 4: The morphology of MNC forward osmosis membranes with amino silane functionality as well as Pt and A...
  
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Beilstein J. Nanotechnol. 2018, 9, 2479–2498, doi:10.3762/bjnano.9.232

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Effect of electrospinning process variables on the size of polymer fibers and bead-on-string structures established with a 2³ factorial design

Paulina Korycka,
Adam Mirek,
Katarzyna Kramek-Romanowska,
Marcin Grzeczkowicz and
Dorota Lewińska

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Published 17 Sep 2018

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1. Figure 1: Scheme of the apparatus for the electrospinning process.
  
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2. Figure 2: (A) A schematic of the measuring procedure of the size of beads and the diameter of the fiber (wher...
  
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3. Figure 3: Geometric shape of the liquid meniscus at the outlet of the nozzle for 20% PVP solution with flow r...
  
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4. Figure 4: SEM micrographs of nanofibers obtained under various conditions: (1) PVP 8% (µ−, Q−, U−); (2) PVP 8...
  
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5. Figure 5: Response surface plots presenting the dependence of the diameter of the obtained bead-free fibers (D...
  
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6. Figure 6: Response surface plots presenting the dependence of the diameter of the obtained bead-free fibers (D...
  
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7. Figure 7: Response surface plots presenting the dependence of the diameter of the obtained bead-free fibers (D...
  
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8. Figure 8: Response surface plots presenting the dependence of the diameter of the obtained beaded fibers (d) ...
  
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9. Figure 9: Response surface plots presenting the dependence of the diameter of the obtained beaded fibers (d) ...
  
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10. Figure 10: Response surface plots presenting the dependence of the diameter of the obtained beaded fibers (d) ...
  
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11. Figure 11: Response surface plots presenting the dependence of the size of obtained beads (d_b) on the electric...
  
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12. Figure 12: Response surface plots presenting the dependence of the size of obtained beads (d_b) on the electric...
  
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13. Figure 13: Response surface plots presenting the dependence of the size of obtained beads (d_b) on the dynamic ...
  
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Beilstein J. Nanotechnol. 2018, 9, 2466–2478, doi:10.3762/bjnano.9.231

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High-temperature magnetism and microstructure of a semiconducting ferromagnetic (GaSb)₁₋_x(MnSb)_x alloy

Leonid N. Oveshnikov,
Elena I. Nekhaeva,
Alexey V. Kochura,
Alexander B. Davydov,
Mikhail A. Shakhov,
Sergey F. Marenkin,
Oleg A. Novodvorskii,
Alexander P. Kuzmenko,
Alexander L. Vasiliev,
Boris A. Aronzon and
Erkki Lahderanta

Full Research Paper
Published 14 Sep 2018

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1. Figure 1: (a) Magnetization as a function of the magnetic field for sample GM3 at T = 300 K. Measurements wer...
  
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2. Figure 2: Room-temperature saturation magnetization (M_sat) as a function of the carrier concentration (N_p) (t...
  
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3. Figure 3: Magnetotransport properties of sample GM3: (a) Field dependence of the anomalous Hall component at ...
  
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4. Figure 4: TEM images of the film cross section after annealing (sample GM3): (a) bright-field image, (b) HRTE...
  
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5. Figure 5: (a,d) HRTEM images of sample areas. (b,e) Corresponding two-dimensional Fourier spectra. (c,f) Calc...
  
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6. Figure 6: AFM (a,c) and MFM (b,d) images of the same surface at 303 K (a,b) and 413 K (c,d). AFM (e) and MFM ...
  
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Beilstein J. Nanotechnol. 2018, 9, 2457–2465, doi:10.3762/bjnano.9.230

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Evidence of friction reduction in laterally graded materials

Roberto Guarino,
Gianluca Costagliola,
Federico Bosia and
Nicola Maria Pugno

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Published 13 Sep 2018

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1. Figure 1: Schematic of the numerical models used in this work. Left: 2D discretization in springs and masses ...
  
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2. Figure 2: Dimensionless friction force as function of time for the non-graded material: SBM solution for dif...
  
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3. Figure 3: Examples of stepwise linearly increasing and triangular property gradients considered in this work ...
  
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4. Figure 4: Effect of a gradient in the local coefficients of friction on the global static coefficient of fric...
  
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5. Figure 5: Propagation of the detachment front at the static friction threshold (left) and immediately after (...
  
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6. Figure 6: Dimensionless friction force as function of time for two values of Δ, calculated using the SBM and ...
  
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7. Figure 7: Effect of a gradient in the local coefficients of friction on the global dynamic coefficient of fri...
  
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8. Figure 8: Effect of a gradient in the local coefficients of friction on the global static coefficient of fric...
  
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9. Figure 9: Effect of a gradient in the Young’s modulus on the global static coefficient of friction, expressed...
  
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10. Figure 10: Effect of a gradient in the Young’s modulus on the global dynamic coefficient of friction, expresse...
  
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11. Figure 11: Effect of a triangular gradient in the Young’s modulus on the global static coefficient of friction...
  
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12. Figure 12: Propagation of the detachment front at the static friction threshold (left) and immediately after (...
  
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Beilstein J. Nanotechnol. 2018, 9, 2443–2456, doi:10.3762/bjnano.9.229

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