Colloidal particle aggregation: mechanism of assembly studied via constructal theory modeling

Scott C. Bukosky,
Sukrith Dev,
Monica S. Allen and
Jeffery W. Allen

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Published 06 May 2021

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1. Figure 1: (a) Schematic of the pairwise DLVO interactions between particles (not to scale). (b) Representativ...
  
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2. Figure 2: (a) 1D array of particles that undergo (b) uniform assembly or (c) non-uniform assembly.
  
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3. Figure 3: (a) Two-dimensional square lattice of particles with a uniform spacing of d. A single particle cent...
  
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4. Figure 4: (a) Two-dimensional hexagonal lattice of particles with a uniform spacing of d. A single particle c...
  
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5. Figure 5: Square lattice. Surface plots of the predicted DLVO force for both uniform (left) and non-uniform (...
  
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6. Figure 6: Hexagonal lattice. Surface plots of the predicted DLVO force for both uniform (left) and non-unifor...
  
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Beilstein J. Nanotechnol. 2021, 12, 413–423, doi:10.3762/bjnano.12.33

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A stretchable triboelectric nanogenerator made of silver-coated glass microspheres for human motion energy harvesting and self-powered sensing applications

Hui Li,
Yaju Zhang,
Yonghui Wu,
Hui Zhao,
Weichao Wang,
Xu He and
Haiwu Zheng

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Published 03 May 2021

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1. Figure 1: (a) The structural design of the single-electrode mode TENG. (b) SEM and (c) EDS measurements of th...
  
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2. Figure 2: (a) Schematic of the working principle of the S-TENG. (b-I) Open-circuit voltage and (b-II) short-c...
  
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3. Figure 3: Open-circuit voltage and short-circuit current of the S-TENG (a, b) as functions of the contact are...
  
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4. Figure 4: (a) Voltage of different capacitors (2.2, 4.7, 10, and 33 μF) as function of the charging time with...
  
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5. Figure 5: Optical image of the power supplied by padding the S-TENG with the hand for (a) a calculator and (b...
  
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6. Figure 6: (a) The position of the S-TENGs on the fingers. (b) Current output of the thumb touching the other ...
  
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Beilstein J. Nanotechnol. 2021, 12, 402–412, doi:10.3762/bjnano.12.32

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The impact of molecular tumor profiling on the design strategies for targeting myeloid leukemia and EGFR/CD44-positive solid tumors

Nikola Geskovski,
Nadica Matevska-Geshkovska,
Simona Dimchevska Sazdovska,
Marija Glavas Dodov,
Kristina Mladenovska and
Katerina Goracinova

Review
Published 29 Apr 2021

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1. Figure 1: Hypothetical mechanisms of extravasation of NDDSs into the BM stroma. The nanoscale carrier could i...
  
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2. Figure 2: Schematic representation of a polyrotaxane nanoconstruct bearing surface-oriented PTK7 aptamers for...
  
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3. Figure 3: Wool-like hollow polycaprolactone (PCL) NDDS for the sequential co-delivery of imatinib mesylate (I...
  
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4. Figure 4: EGFR targeting strategies using “non-conventional” ligands. (a) Heparin nanoparticles with surface-...
  
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5. Figure 5: A multifunctional hyaluronan nanogel targeting EGFR and CD44. The binding of hyaluronan residues an...
  
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6. Figure 6: HA-functionalized NDDS with multimodal targeting capabilities. (a) HA–paclitaxel (PTX) complex and ...
  
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Beilstein J. Nanotechnol. 2021, 12, 375–401, doi:10.3762/bjnano.12.31

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Spontaneous shape transition of Mn_xGe₁₋_x islands to long nanowires

S. Javad Rezvani,
Luc Favre,
Gabriele Giuli,
Yiming Wubulikasimu,
Isabelle Berbezier,
Augusto Marcelli,
Luca Boarino and
Nicola Pinto

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Published 28 Apr 2021

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1. Figure 1: SEM images of the morphological evolution of strained Mn wetting layers with different thickness af...
  
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2. Figure 2: X-ray diffraction pattern of the 9 ML thick Mn wetting layer, upon annealing at 650 °C for 15 min. ...
  
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3. Figure 3: SEM images of the surface after deposition of 4.5 ML Mn on Ge(111) wafer and annealing at 650 °C fo...
  
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4. Figure 4: (a) SEM image of a typical NW, ≃700 nm long, obtained by deposition of a 4.5 ML thick Mn film follo...
  
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5. Figure 5: EDX elemental map (Kα line), carried out on a cross-section of a NW on the surface of the 4.5 ML th...
  
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6. Figure 6: Cross-section image of the NW along its length. (a) TEM image of a 1.15 μm long NW capped with a Pt...
  
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7. Figure 7: (a) Length (t) and width (s) of Mn₅Ge₃ islands, formed on the sample surface of the 4.5 ML thick Mn...
  
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Beilstein J. Nanotechnol. 2021, 12, 366–374, doi:10.3762/bjnano.12.30

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Structural and optical characteristics determined by the sputtering deposition conditions of oxide thin films

Petronela Prepelita,
Florin Garoi and
Valentin Craciun

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Published 19 Apr 2021

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1. Figure 1: XRD patterns of ZnO thin film samples with different thickness, namely: 200, 250, and 300 nm.
  
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2. Figure 2: XPS patterns of SiO₂ thin films: general spectra.
  
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3. Figure 3: High-resolution XPS spectra acquired from SiO₂ samples: (a) Si 2p3 and (b) O 1s.
  
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4. Figure 4: XPS survey spectra acquired from ZnO films.
  
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5. Figure 5: High-resolution (a) Zn 2p3 and (b) O 1s XPS spectra acquired from ZnO samples.
  
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6. Figure 6: Cross-sectional SEM images of the cleaved SiO₂ films with measured thickness values of (a) d_SiO2 = ...
  
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7. Figure 7: Cross-sectional SEM images of the cleaved ZnO films with measured thickness values of (a) d_ZnO = 20...
  
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8. Figure 8: Transmission spectra of thin films with various thickness values (200, 250, and 300 nm): (a) SiO₂ a...
  
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9. Figure 9: Extinction coefficient dependence on the wavelength for (a) SiO₂ and (b) ZnO thin films.
  
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10. Figure 10: Dependence of (αhν)² = f(hν) on the energy of the incident photons for (a) SiO₂ and (b) ZnO samples...
  
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11. Figure 11: Refractive index dependence on the wavelength (dispersion) for (a) SiO₂ and (b) ZnO thin films.
  
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12. Figure 12: Photon energy dependence of the (a) real and (b) imaginary parts of permittivity for SiO₂ (i) and Z...
  
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Beilstein J. Nanotechnol. 2021, 12, 354–365, doi:10.3762/bjnano.12.29

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Nickel nanoparticle-decorated reduced graphene oxide/WO₃ nanocomposite – a promising candidate for gas sensing

Ilka Simon,
Alexandr Savitsky,
Rolf Mülhaupt,
Vladimir Pankov and
Christoph Janiak

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Published 15 Apr 2021

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1. Figure 1: P-XRD pattern of Ni@rGO obtained from a 0.5 wt % dispersion of Ni(COD)₂ in [BMIm][NTf₂] (space grou...
  
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2. Figure 2: TEM images of Ni@rGO obtained from a 0.5 wt % dispersion of Ni(COD)₂ in [BMIm][NTf₂]. Particle size...
  
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3. Figure 3: Left: P-XRD pattern of WO₃ powder calcined at 600 °C for 2 h. (space group of WO₃: P2₁/n). Right: S...
  
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4. Figure 4: Time dependence of the sensor resistance values of the 0.35 wt % Ni@rGO/WO₃ sample under exposure t...
  
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5. Figure 5: Left: time dependence of the sensor resistance values of the 0.35 wt % Ni@rGO/WO₃ samples (green) u...
  
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6. Figure 6: Time dependence of the sensor resistance values (left) and sensor response (right) of 1.00 wt % Ni@...
  
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7. Figure 7: Left: magnetization as a function of temperature for the Ni@rGO composite in argon atmosphere. Righ...
  
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Beilstein J. Nanotechnol. 2021, 12, 343–353, doi:10.3762/bjnano.12.28

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Intracranial recording in patients with aphasia using nanomaterial-based flexible electronics: promises and challenges

Qingchun Wang and
Wai Ting Siok

Review
Published 08 Apr 2021

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1. Figure 1: Wernicke’s-Lichtheim model (redrawn from [12], Figure 2). A: The Wernicke’s area. M: The Broca’s area. a: The p...
  
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2. Figure 2: iEEG detects brain activity by implanting electrodes on the cortical surface. (a) Strips and grids ...
  
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3. Figure 3: iEEG recording of patients with medically intractable epilepsy. (a) Electrodes were implanted in th...
  
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4. Figure 4: ERP analysis suggests semantic priming centralises in the left temporal cortex, whereas perceptual ...
  
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5. Figure 5: Features of the iWEBS array. (a) Implantation in free-moving mice. (b) Layer components. (c) Struct...
  
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Beilstein J. Nanotechnol. 2021, 12, 330–342, doi:10.3762/bjnano.12.27

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Exploring the fabrication and transfer mechanism of metallic nanostructures on carbon nanomembranes via focused electron beam induced processing

Christian Preischl,
Linh Hoang Le,
Elif Bilgilisoy,
Armin Gölzhäuser and
Hubertus Marbach

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Published 07 Apr 2021

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1. Figure 1: (a) SAM consisting of TPT molecules on a Ag(111)/mica substrate. (b) EBID process on the SAM Ag sub...
  
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2. Figure 2: Results of FEBIP experiments followed by autocatalytic growth on a TPT SAM on Ag(111)/mica. All str...
  
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3. Figure 3: Results of time-dependent EBISA experiments followed by autocatalytic growth on a TPT SAM on Ag(111...
  
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4. Figure 4: Transfer of a CNM with a Fe structure on top onto a SiO₂ sample. (a) SEM image of a Fe structure fa...
  
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5. Figure 5: Transfer of a CNM with Fe structures on top onto a SiO₂ sample. (a) SEM image of the Fe structures ...
  
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6. Figure 6: Transfer of a CNM with a cobalt oxide structure on top onto a SiO₂ sample. (a) SEM image of a cobal...
  
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7. Figure 7: Schematic result of the transfer process. (a) Fe structure on top of a TPT SAM on a Ag(111)/mica sa...
  
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Beilstein J. Nanotechnol. 2021, 12, 319–329, doi:10.3762/bjnano.12.26

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The patterning toolbox FIB-o-mat: Exploiting the full potential of focused helium ions for nanofabrication

Victor Deinhart,
Lisa-Marie Kern,
Jan N. Kirchhof,
Sabrina Juergensen,
Joris Sturm,
Enno Krauss,
Thorsten Feichtner,
Sviatoslav Kovalchuk,
Michael Schneider,
Dieter Engel,
Bastian Pfau,
Bert Hecht,
Kirill I. Bolotin,
Stephanie Reich and
Katja Höflich

Full Research Paper
Published 06 Apr 2021

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1. Figure 1: FIB-o-mat overview. (a) For patterning the beam spot follows a rasterized beam path with a defined ...
  
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2. Figure 2: Geometric primitives and rasterization styles available for high-level pattern generation. (a) Sing...
  
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3. Figure 3: Geometric entities and rasterization styles available for low-level pattern generation. (a) Pre-ras...
  
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4. Figure 4: Geometry-optimized patterning. (a) Beam path generation by curve off-setting around arbitrary disco...
  
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5. Figure 5: Magnetic nanopatterning of a Co/Pt multilayer. Fourier-transform holography (FTH) images (a–f) with...
  
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6. Figure 6: Single-layer graphene resonator. (a) Secondary electron He ion microscopy image of the graphene res...
  
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7. Figure 7: Coupled plasmonic antennas. (a–c) Scanning electron micrographs of gold tetramers on glass with a t...
  
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8. Figure 8: Optimized tetramer. Secondary electron He ion microscopy images of gold tetramers on glass with min...
  
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Beilstein J. Nanotechnol. 2021, 12, 304–318, doi:10.3762/bjnano.12.25

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Doxorubicin-loaded gold nanorods: a multifunctional chemo-photothermal nanoplatform for cancer management

Uzma Azeem Awan,
Abida Raza,
Shaukat Ali,
Rida Fatima Saeed and
Nosheen Akhtar

Full Research Paper
Published 31 Mar 2021

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1. Figure 1: (a) TEM image of monodispersed GNRs. (b) Histogram showing the aspect ratio of GNRs. (c) UV–vis abs...
  
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2. Figure 2: PSS-GNRs before and after 808 nm laser exposure, the LSPR peak shifted about 4 nm.
  
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3. Figure 3: In vitro DOX release profile from PSS-GNRs. (a) NIR-triggered DOX release at different pH values. F...
  
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4. Figure 4: (a) Relative viabilities of HepG2 and 3T3 cells after being incubated with different concentrations...
  
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5. Figure 5: (a) Percentage viabilities of HepG2 cells treated with free DOX and DOX-PSS-GNRs exposed to NIR lig...
  
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Beilstein J. Nanotechnol. 2021, 12, 295–303, doi:10.3762/bjnano.12.24

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Colloidal particle aggregation: mechanism of assembly studied via constructal theory modeling

A stretchable triboelectric nanogenerator made of silver-coated glass microspheres for human motion energy harvesting and self-powered sensing applications

The impact of molecular tumor profiling on the design strategies for targeting myeloid leukemia and EGFR/CD44-positive solid tumors

Spontaneous shape transition of Mn_xGe₁₋_x islands to long nanowires

Structural and optical characteristics determined by the sputtering deposition conditions of oxide thin films

Nickel nanoparticle-decorated reduced graphene oxide/WO₃ nanocomposite – a promising candidate for gas sensing

Intracranial recording in patients with aphasia using nanomaterial-based flexible electronics: promises and challenges

Exploring the fabrication and transfer mechanism of metallic nanostructures on carbon nanomembranes via focused electron beam induced processing

The patterning toolbox FIB-o-mat: Exploiting the full potential of focused helium ions for nanofabrication

Doxorubicin-loaded gold nanorods: a multifunctional chemo-photothermal nanoplatform for cancer management

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