Keywords: Tin; Laser pyrolysis; Nanopowder; Li-ion batteries; 61.46.Df; 68.35.bd; 81.16.Mk; 81.07.Bc;
مقالات ISI (ترجمه نشده)
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Keywords: 81.16.Mk; 81.07.Bc; 79.20.Ds; Laser-assisted microablation; Surface plasmon-polariton resonance; Nanoparticles implantation; Polymer film;
Keywords: Laser pyrolysis; Iron-based magnetic nanocomposites; Titania; 81.16.Mk; 75.75.Fk; 85.70.âw; 81.07.Wx; 61.46.Df;
Synthesis and characterization of polyaniline-Fe@C magnetic nanocomposite powder
Keywords: 81.16.Mk; 75.50.Bb; 72.80.Le; 82.80.Fk; Laser pyrolysis; Magnetic nanocomposite; Polyaniline;
Highly magnetic Fe2O3 nanoparticles synthesized by laser pyrolysis used for biological and heat transfer applications
Keywords: 81.16.Mk; 65.80.âg; 87.85.Qr; 87.85.Rs; 82.70.Kj; 75.75.fk; Laser pyrolysis; Ferrofluid; l-DOPA; Low cytotoxicity;
Synthesis and optical properties of TiO2-based magnetic nanocomposites
Keywords: Laser pyrolysis; Nanoparticles; Band-gap; Magnetic properties; 81.16.Mk; 75.50.Tt; 78.67.Bf;
Enhancing the visible light absorption of titania nanoparticles by S and C doping in a single-step process
Keywords: Laser pyrolysis; Nanoparticles; C; S-modified TiO2; Band gap energy; UV-Vis spectroscopy; 81.16.Mk; 61.46.Df; 78.67.Bf;
Novel Fe@C-TiO2 and Fe@C-SiO2 water-dispersible magnetic nanocomposites
Keywords: 81.16.Mk; 81.20.Fw; 75.75.Fk; 85.70.âw; Laser pyrolysis; Iron-based magnetic nanocomposites; Silica or titania shells;
Structural properties of pulsed laser deposited SnOx thin films
Keywords: 81.16.Mk; 68.37.Lp; 61.46.Df; Tin oxide; Thin films; Pulsed laser ablation; TEM;
Position-controlled synthesis of single-walled carbon nanotubes on a transparent substrate by laser-induced chemical vapor deposition
Keywords: 81.16.Mk; 81.07.De; 81.16.Hc; Laser chemical vapor deposition; Single-walled carbon nanotubes; Laser direct writing; Multiple-catalyst layer;
Influence of the laser wavelength on the epitaxial growth and electrical properties of La0.8Sr0.2MnO3 films grown by excimer laser-assisted MOD
Keywords: 74.25.Fy; 07.07.Df; 81.16.Be; 81.16.Mk; 81.15.Np; 81.65.âb; LSMO; Epitaxial; TCR; ELAMOD;
The nobel solution process using the extreme energy state for anisotropic structured nanomaterials
Keywords: 62.23.Kn; 81.16.Mk; 68.37.LpAnisotropic structured nanomaterial; Laser ablation under solution process; Ag
Aligned growth of ZnO nanowires by NAPLD and their optical characterizations
Keywords: 81.07.Bc; 78.66.Hf; 78.67.Bf; 81.16.Mk; ZnO; Nanostructures; Pulsed-laser deposition; Optical properties;
Direct writing of carbon nanotube patterns by laser-induced chemical vapor deposition on a transparent substrate
Keywords: 81.16.Mk; 81.07.De; 81.16.Hc; Laser chemical vapor deposition; Carbon nanotube; Laser direct writing; Multiple-catalyst-layer;
Direct conversion of a metal organic compound to epitaxial Sb-doped SnO2 film on a (0Â 0Â 1) TiO2 substrate using a KrF laser, and its resulting electrical properties
Keywords: 74.25.Fy; 81.16.Be; 81.16.Mk; 81.15.Np; 81.65.âb; Sb-doped SnO2; Epitaxial; Excimer laser;
Surface morphology and luminescence characterization of β-FeSi2 thin films prepared by pulsed laser deposition
Keywords: 78.66.Li; 61.30.Pq; 81.16.Mk; 78.55.âm; β-FeSi2; Droplet; Pulsed laser deposition; Photoluminescence;
Characterization of ultra-fast deposited polycrystalline graphite by a CO2 laser-assisted combustion-flame method
Keywords: 81.05.Uw; 81.16.Mk; 68.37.Hk; High deposition rate; Crystalline graphite; Laser-assisted combustion-flame deposition;
Structure, morphology and properties of Fe-doped ZnO films prepared by facing-target magnetron sputtering system
Keywords: 68.55.âa; 71.55.Gs; 74.25.Gz; 74.25.Ha; 81.16.Mk; Fe-doped ZnO films; Structure; Morphology; Properties; Facing-target magnetron sputtering system;
Fabrication of microelectrodes deeply embedded in LiNbO3 using a femtosecond laser
Keywords: 42.62.Cf; 77.84.âs; 78.20.Jq; 81.16.Mk; Selective electroless plating; Femtosecond pulsed laser; Microelectrode; Lithium niobate;
Effects of an external magnetic field in pulsed laser deposition
Keywords: 52.38.Mf; 81.15.Fg; 81.16.Mk; 52.38.Fz; Magnetic field; Laser ablation; Laser deposition;
Substrate effects on ZnO nanostructure growth via nanoparticle-assisted pulsed-laser deposition
Keywords: 81.07.Bc; 78.66.Hf; 78.67.Bf; 81.16.Mk; ZnO; Nanostructures; Pulsed-laser deposition; Optical properties;
Plume propagation through a buffer gas and cluster size prediction
Keywords: 79.20.Ds; 52.38.Mf; 81.16.Mk; Pulsed laser deposition; Plume expansion; Cluster synthesis; Carbon; Silver;
Laser synthesis of semiconductor nanostructures with narrow band gap
Keywords: 81.16.Mk; 73.22âf; Laser deposition; Thin films; Laser crystallization;
Influence of laser heating on adhesion of CVD coatings to cutting edges
Keywords: 81.16.Mk; 81.15.GhWear-resistant coatings; Laser heating; Cutting tools
Pulsed laser deposition of multiwalled carbon nanotubes thin films
Keywords: 81.16; 81.15.Fg; 81.16.Mk; 79.20.Ds; 78.30.J; 68.37.Lp; 68.49.Uv; 82.45.Mp; 78.67.ch; 61.46.Fg; IDORE; Laser deposition; Nanotubes;
The effect of melting-induced volumetric expansion on initiation of laser-induced forward transfer
Keywords: 81.16.Mk; 42.62âb; 44.05.+e; 68.18.Jk; Laser-induced forward transfer; Microfabrication; Thin film; Phase change;
Control of cluster synthesis in nano-glassy carbon films
Keywords: 81.16.Mk; 61.46.Bc; 81.05.Uw; 78.30.−jRaman scattering; Laser deposition; Carbon; Laser–matter interaction; Scanning electron microscopy; Nanoclusters; Carbon-based and nanotubes; Short-range order
A sensor for adenosine triphosphate fabricated by laser-induced forward transfer of luciferase onto a poly(dimethylsiloxane) microchip
Keywords: 81.15.Fg; 81.16.Mk; 87.15.Mi; 87.66.Sq; Enzyme; Luciferase; Luciferin; LIFT; Luminescence;
Carbon nanotubes growth from C2H2 and C2H4/NH3 by catalytic LCVD on supported iron–carbon nanocomposites
Keywords: 81.16.Mk; 81.07.De; 68.37.Lp; 68.37.HkCargon nanotubes; Catalytic LCVD; Fe–C nanocomposites; Ammonia precursor; Coiled shape
Influence of ambient gas ionization on the deposition of clusters formed in an ablation plume
Keywords: 51.50.+v; 36.40.Sx; 81.16.Mk; 81.07.Bc; Pulsed laser deposition; Plume dynamics; Ionization; Cluster-assembled films; Carbon;
Laser synthesis of nanostructures based on transition metal oxides
Keywords: 81.16.Mk; 73.22âf; Laser deposition; Thin films; Quantum dimensional effect;
Pulsed laser deposition prepared LiMn2O4 thin film
Keywords: 82.47.Aa; 81.16.Mk; 71.35.Cc; 68.60.WmPulse laser deposition; Batteries; Fuel cells; Scanning electron microscopy; Optical properties
Study of pulsed laser-deposited phosphorus-doped carbon/p-silicon photovoltaic cell
Keywords: 85.60.Bt; 81.16.Mk; 81.05.Uw; A1. C-V modeling; A3. PLD carbon thin film; B3. n-C/P-Si heterostructure;
Preparation and characterization of C54 TiSi2 nanoislands on Si (1 1 1) by laser deposition of TiO2
Keywords: 81.07.-b; 61.46.+w; 68.37.Ef; 81.16.Mk; Nanostructure; Titanium silicide; Scanning tunneling microscopy; Laser ablation;
Laser photodeposition of thin semiconductor films from iron carbonyl vapors
Keywords: 81.16.Mk; 73.22-f; Laser deposition; Carbonyl vapor; Thin films;
Magnetic properties of iron/graphite core-shell nanoparticles prepared by annealing of Fe-C-N-based nanocomposite
Keywords: 81.16.Mk; 81.07.Wx; 75.75.+a; Nanocrystalline materials; Particles-single domain; Mössbauer spectroscopy-fine particles; Annealing; Precipitation;
Epitaxial growth of tin oxide films on (0Â 0Â 1) TiO2 substrates by KrF and XeCl excimer laser annealing
Keywords: 81.15.Fg; 81.15.-z; 81.16.Mk; 82.50.Hp; 73.61.Le; SnO2; Excimer laser; KrF; XeCl; MOD; Epitaxial growth; (0Â 0Â 1) TiO2;
Scaling law of angular emission distributions of laser ablated particle pulses from monoatomic and compound targets
Keywords: 41.75.âi; 52.70.Nc; 52.38.Mf; 79.20.Ds; 81.15.Fg; 81.16.Mk; Mono- and biatomic laser ablated particle beams; Angular emission distributions; Scaling laws of emission shapes;