- Full Research Paper
- Published 21 Jan 2020
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Figure 1: Schematic illustration of the preparation of the uniform hierarchical NiMoO4@Co3O4/CA sample.
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Figure 2: (a) SEM image of CA; (b) SEM and (c) TEM images of NiMoO4/CA; (d) SEM image of NiMoO4@ZIF-67/CA; (e...
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Figure 3: (a) XRD patterns of Co3O4, CA, NiMoO4 and NiMoO4@Co3O4/CA (from top to bottom); (b) EDS spectrum; (...
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Figure 4: XPS spectra of the NiMoO4@Co3O4/CA composite: (a) Survey spectrum; (b-f) Core-level spectra of (b) ...
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Figure 5: Nitrogen adsorption/desorption isotherms and pore size distribution curves of (a) CA, (b) NiMoO4/CA...
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Figure 6: (a) Cyclic voltammetry (CV) curves at scan rates of 2.5–50 mV/s and (b) galvanostatic charge/discha...
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Figure 7: Electrochemical performance of the NiMoO4@Co3O4/CA//AC ASC. (a) Schematic illustration of the ASC d...
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- Full Research Paper
- Published 20 Jan 2020
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Figure 1: (a) Schematic picture of a QD coupled to pure monolayer graphene electrodes at its left (L) and rig...
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Figure 2: The DOS in the QD for different values of the chemical potentials at temperature T/D = 5 × 10−6 wit...
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Figure 3: The nonequilibrium DOS in the QD at zero magnetic field for different temperatures with U/D → ∞ and...
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Figure 4: The nonequilibrium DOS in the QD for different values of the Zeeman energy with U/D → ∞ at temperat...
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Figure 5: Differential conductance dI/dV as a function of the bias voltage eV with μR/D = −0.022 at three dif...
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Figure 6: Differential conductance dI/dV as a function of the bias voltage eV for different values of the che...
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Figure 7: Amplitude of the zero-bias peak as a function of the chemical potential μR for eV = 0 at three diff...
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Figure 8: Differential conductance dI/dV as a function of the bias voltage eV for different values of the Zee...
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Figure 9: The nonequilibrium DOS in the QD for U/D = 0.069 with μL/D = 25 × 10−3 and μR/D = −9.5 × 10−3 at th...
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Figure 10: The nonequilibrium DOS in the QD for different values of the Zeeman energy and finite U at temperat...
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Figure 11: Differential conductance dI/dV as a function of the bias voltage eV with μR/D = −9.5 × 10−3 for dif...
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- Published 17 Jan 2020
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Figure 1: Influence of the salinity of the aqueous phase on the phase inverson zone (PIZ) for the nanoemulsio...
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Figure 2: Ternary phase diagrams giving the particle diameter and the PDI of the nonisotonic nanoemulsions pr...
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Figure 3: Ideal osmolality of aqueous sodium chloride solutions after Ph. Eur. 2.2.35 and experimental osmola...
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Figure 4: Ternary phase diagrams showing (a) the resulting particle diameter, (b) the PDI, (c) the zeta poten...
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Figure 5: Particle diameters and PDI of the nanoemulsions depending on the Kolliphor HS 15:MCT ratio.
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Figure 6: Long-term stability of four selected nanoemulsions with particles of approximately 25 (NE25), 50 (N...
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Figure 7: Viability of the cells of lines 3T3 and NHDF as a function of the Kolliphor HS 15 concentration cKol...
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Figure 8: Morphology of the 3T3 and NHDF cells after 24 h incubation ion solutions with a concentration of th...
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Figure 9: Scheme of the experimental set-up and the method of phase inversion-based production of the nanoemu...
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- Review
- Published 15 Jan 2020
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Figure 1: Schematic description of in vitro PDT processes using photosensitizer (PS) encapsulated in a block ...
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Figure 2: Chemical structures of four molecular photosensitizers commonly used: a) pheophorbide a; b) chlorin...
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Figure 3: Schematic representation of the strategies used for delivery of photosensitizers using block copoly...
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Figure 4: Chemical structures of the main blocks commonly described in recent literature.
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Figure 5: a) Light-responsive self-immolative polymers. Adapted with permission from [70], copyright 2018 America...
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Figure 6: Block copolymers used as nanocarriers for overcoming hypoxia; a) adapted with permission from [104], cop...
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Figure 7: Schematic representation of the interplay between polymer structure, physicochemical characteristic...
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Figure 8: Representative snapshots describing the endocytosis pathway for spherocylindrical nanoparticles. Re...
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Figure 9: Field flow fractograms of PEO(2400)-b-PDLLA(2000) and PEO(3100)-b-PS(2300) micelles. The multi-angl...
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Figure 10: Idealized docking of 5,10,15,20-tetrakis(3-hydroxyphenyl)chlorin (m-THPC, shown as van der Waals su...
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Figure 11: Modulation of PDT efficiency through introduction of bulky substituents on the PS, which inhibit ag...
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Figure 12: Use of Hansen solubility parameters to optimize polymeric nanovectors.
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Figure 13: Types of pathways of block copolymer micelle–cell membrane interactions. Reprinted with permission ...
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Figure 14: Schematic view of photodynamic therapy (PDT) strategies with polymeric nanovectors targeting subcel...
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Figure 15: Illustration of the PTX@PAsp-g-(PEG-ICG) ER-targeting process and mechanism of cell death. PTX@PAsp-...
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- Full Research Paper
- Published 14 Jan 2020
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Figure 1: SEM images of a) G1, b) G2, c) G3, d) HDPE/G1 nanocomposite with 5.52 vol %, e) HDPE/G2 nanocomposi...
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Figure 2: XPS: a) survey and b) C 1s high-resolution spectra for G1, G2, and G3.
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Figure 3: a) FTIR spectrum and b) XRD pattern of the GnPs, pure HDPE, and HDPE/13.94 vol % GnP nanocomposites....
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Figure 4: Real part of AC electrical conductivity vs frequency for a) HDPE/G1, b) HDPE/G2, and c) HDPE/G3 nan...
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Figure 5: The relative thermal conductivity values of HDPE-based nanocomposites with G1, G2, and G3 fillers (k...
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Figure 6: Relative mechanical properties of the HDPE/GnP nanocomposites: a) Young’s moduli and b) tensile str...
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Figure 7: TGA thermographs of the HDPE/GnP nanocomposites with a) G1, b) G2, and c) G3 filler. The insets sho...
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- Published 13 Jan 2020
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Figure 1: Schematic of the manipulation process of a cylindrical nanoparticle by means of AFM.
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Figure 2: Nanoparticle manipulation forces and angles in a) 3D view and b) side view.
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Figure 3: Timoshenko beam model: kinematic parameters, loading and coordinate system [27].
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Figure 4: General algorithm for dynamic and mechanical modeling.
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Figure 5: Simulation of critical times and forces in sliding and rolling modes for a gold nanoparticle with a...
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Figure 6: Simulations of the variation of the tip force angle (α) during the manipulation process until achie...
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Figure 7: Classical and nonclassical modeling of the deflections of a cylindrical gold nanoparticle (length =...
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Figure 8: Classical and nonclassical modeling of the rotation angles of a cylindrical gold nanoparticle (leng...
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Figure 9: Natural frequencies of the classical and nonclassical models of a cylindrical gold nanoparticle wit...
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Figure 10: Sensitivity of classical and nonclassical Timoshenko beam model deflections to the change in aspect...
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Figure 11: Simulation of motion of a cylindrical gold nanoparticle during a manipulation of 200 nm. A) Aspect ...
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Figure 12: The sensitivity of manipulation dynamics to size effects (length = 25 µm and aspect ratio = 30).
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Figure 13: Manipulation of the nonclassical Timoshenko model for 0.5l and 1.5l.
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Figure 14: Classical stresses in a cylindrical gold nanoparticle with a length of 25 µm and aspect ratio of 30....
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Figure 15: Equivalent stresses (nonclassical) in a cylindrical gold nanoparticle with a length of 25 µm and as...
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Figure 16: Comparison of the classical stresses and nonclassical equivalent stresses with respect to changes i...
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Figure 17: Variation of nonclassical equivalent stresses with material length scale parameter and change in as...
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Figure 18: Comparison of the critical force and time simulation using the JKR contact model for a gold particl...
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Figure 19: Comparison of the critical force and time simulation using the Lundberg cylindrical contact model f...
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Figure 20: Comparison of the deflections of a polystyrene nanorod using classical and nonclassical models assu...
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Figure 21: Comparison of polystyrene nanorod deflections in the nonclassical Timoshenko beam model with respec...
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Figure 22: Simulation of the manipulation process of a polystyrene nanorod and comparison with the presented m...
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Figure 23: Variation of the failure aspect ratio versus l/d for a polystyrene nanorod.
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- Letter
- Published 10 Jan 2020
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Figure 1: Formation of Ag-modified TiO2 HSs (top) and SEM images showing Ag–TiO2 nanostructures at different ...
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Figure 2: SEM images of freshly prepared Ag–TiO2 core–shell nanostructures (A) and Ag–TiO2 core–shell nanostr...
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Figure 3: XPS Ag 3d1/2 and Ag 3d5/2 spectra of freshly prepared Ag–TiO2 core–shell structures (top) and after...
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Figure 4: UV–vis spectra and images of aqueous suspensions of freshly prepared Ag–TiO2 core–shell nanostructu...
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Supp. Info
- Review
- Published 09 Jan 2020
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Figure 1: Illustration of conventional (WC) and unconventional (non-WC) hydrogen bonding interactions between...
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Figure 2: Molecular design and engineering of DNA nanoarchitectures using different types of DNA modules. The...
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Figure 3: Schematic representation of DNA tetrahedron-based electroluminescence biosensor platforms. The imag...
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Figure 4: a) Schematic representation of mutually templated double-helical zipper assemblies of APA and dBn (...
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Figure 5: a) Mutually templated coassembly of BNA and dTn (n = 6, 10, 20) to form a BNAn–dTn hybrid ensemble,...
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Figure 6: Molecular structures of nucleobase-tethered NDI molecules (NDI-AA and NDI-TT) and their assembly, c...
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Figure 7: a) Zn(II)-cyclen-tethered NDI and DPP SFMs. b) DPP–dT40 and NDI–dT40 multichromophore arrays over a...
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Figure 8: a) Schematic representation of a porphyrin-appended DNA nanopore base lipid anchor. b) AFM image of...
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- Review
- Published 09 Jan 2020
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Figure 1: Mechanisms of CPP uptake. Two main mechanisms have been proposed: direct translocation through the ...
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Figure 2: Model for the initial step of cellular uptake of MPG or MPG/cargo complexes. (1) Binding of MPG or ...
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Figure 3: Mechanisms of endocytic entry into the cell. Reprinted with permission from [53], copyright 2011 The Ro...
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Figure 4: Most commonly used strategies for improving the endosomal release of CPPs. A) Fusogenic lipids, B) ...
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- Full Research Paper
- Published 08 Jan 2020
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Figure 1: (a) Representative I(V) trace of an Ag/AgI/PtIr nanojunction demonstrating resistive switching beha...
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Figure 2: (a) The color scale shows the OFF-to-ON-resistance ratio, ROFF/RON, of a stable Ag/AgI/PtIr nanojun...
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Figure 3: (a) A full cycle of a pulsing experiment consisting of Vdrive (green) voltage pulses with ±0.5 V am...
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Figure 4: (a) The schematics of the high-frequency measurement setup. The PtIr tip and the AgI/Ag thin film a...
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Figure 5: (a) Subsequent set and reset transitions triggered by the voltage pulses fired by G1 and G2, respec...
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