Keywords: 81.16.-c; 68.03 Cd; 67.37.âd; 68.37. Hk; 68.37.Lp; 68.47.De; 81.65.âb; 81.16.âc; Pyramid; Electron beam; Ion beam; Surface free energy; Surface modification; Plasmonic nanopore;
مقالات ISI 81.16.-c (ترجمه نشده)
مقالات زیر هنوز به فارسی ترجمه نشده اند.
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در صورتی که به ترجمه آماده هر یک از مقالات زیر نیاز داشته باشید، می توانید سفارش دهید تا مترجمان با تجربه این مجموعه در اسرع وقت آن را برای شما ترجمه نمایند.
Fabrication of the similar porous alumina silicon template for soft UV nanoimprint lithography
Keywords: 81.16.-c; 81.16.âc; 42.25.Gy; 78.67.ân; 81.07.âb; Porous alumina template; Nonflatness; Anodization; Soft UV nanoimprint lithography;
S-termination effects for the catalytic activities of Pd on GaN(0 0 0 1) surfaces
Keywords: 81.16.-c; 81.16.Hc; 68.35.bj; 81.16.âc; Pd; GaN; S; Catalyst; Mizoroki-Heck reaction;
Fe-inserted and shell-shaped carbon nanoparticles by cluster-mediated laser pyrolysis
Keywords: 81.16.-c; 82.30.Lp; 81.16.âc; 81.07.âb; 62.23.Pq; Laser pyrolysis; Iron-carbon nanoparticles; Shell-shape nanoparticles;
Ripple topography on thin ZnO films by grazing and oblique incidence ion sputtering
Keywords: 81.16.-c; 61.80.Jh; 81.16.âc; 79.20.Rf; 81.16.Rf; 79.20.Ap; Sputtering; Ripple; Grazing incidence; ZnO;
Damage mechanism and morphology characteristics of chromium film in femtosecond laser rear-side ablation
Keywords: 81.16.-c; 42.82.Cr; 42.62.Cf; 81.16.âC; Femtosecond laser; Rear-side ablation; Damage mechanism; Morphology characteristics; Nano-ripples;
Photoluminescence investigation of ZnO:P nanoneedle arrays on InP substrate by pulsed laser deposition
Keywords: 81.16.-c; 81.07.Bc; 81.16.âc; 61.46.Hk; ZnO; Nanoneedle arrays; Photoluminescence; Phosphorus-doped;
Comparing morphology studies of GaAs quantum dots grown by droplet epitaxy on GaInP and GaAs
Keywords: 81.16.-c; A1. Nanostructures; A1. Quantum dots; A3. Molecular beam epitaxy; 61.46.âw; 68.55.ag; 73.21.La; 78.67.Hc; 81.16.âc;
Post-treatment of mesoporous material with high temperature for synthesis super-microporous materials with enhanced hydrothermal stability
Keywords: 81.16.-c; 82.75.âz; 81.07.âb; 81.16.âc; MCM-48; Mesoporous; Super-microporous; Hydrothermal stability;
Large-area silica nanotubes with controllable geometry on silicon substrates
Keywords: 81.16.-c; 81.16.Rf; 81.16.âc; Silica nanotubes; AAO thin film; Ion beam technology;
Growth and properties of ZnO nanorod and nanonails by thermal evaporation
Keywords: 81.16.-c; 79.60.Jv; 81.16.âc; 81.15.Gh; 73.61Ga; Nanostructures; Crystal growth; Chemical vapor deposition processes; Zinc oxide; Semiconducting II-VI material;
Feasibility study of barium fluoride films as a sacrificial layer for patterning of ZnO nanowire arrays
Keywords: 81.16.-c; 81.05.Dz; 81.07.âb; 81.15.Gh; 81.16.âc; A1. Etching; A1. Nanostructures; A3. Metal-organic chemical vapor deposition; B1. Barium fluoride; B1. Zinc oxide; B2. Semiconducting materials;
Study of temperature rise during focused Ga ion beam irradiation using nanothermo-probe
Keywords: 81.16.-c; 81.15.Jj; 81.16.âc; 47.80.Fg; Focused ion beam; Nanostructure fabrication; SEM; Nanothermocouple;
Ultra fast melting process in femtosecond laser crystallization of thin a-Si layer
Keywords: 81.16.-c; 81.16.âc; 82.53.Mj; 81.07.âb; 68.55.âa; 61.50.âf; 68.37.âd; Femtosecond laser; Crystallization; Pump-Probe measurement; TEM; Amorphous silicon; Liquid silicon;
The role of collisions in the aligned growth of vertical nanowires
Keywords: 81.16.-c; 81.05.Ea; 81.07.Vb; 81.15.Gh; 81.16.âc; A1. Nanostructures; A3.Metalorganic chemical vapor deposition; A3. Vapor phase epitaxy; B1. Nitrides; B2. Semiconducting gallium compounds; B2. Semiconducting III-V materials;
Synthesis of GaN nanowires by Tb catalysis
Keywords: 81.16.-c; 68.65.âk; 78.30.Fs; 81.16.âc; GaN; Nanowires; Sputtering; Single-crystal growth;
FRET structure with non-radiative acceptor provided by dye-linker-glass surface complex and single-molecule photodynamics by TIRFM-polarized imaging
Keywords: 81.16.-c; 81.05.ât; 81.07.âb; 81.16.âc; 81.20.ân; 82.37.âj; TIRFM; Single-molecule imaging; FRET structure; Non-radiative relaxation; Anisotropy;
Synthesis of CdII-4,4â²-bipy coordination polymer nanorods with tunable size and shape
Keywords: 81.16.-c; 81.16.âc; 61.82.Rx; Nanorods; Coordination polymer; Cadmium; 4; 4â²-bipy;
Characterization of anti-adhesive self-assembled monolayer for nanoimprint lithography
Keywords: 81.16.-c; 81.15.Kk; 81.16.Rf; 68.37.Ps; 81.16.Dn; 81.16.âC; Anti-adhesive; Self-assembled monolayer; FDTS; UV-nanoimprint lithography;
Elaboration of self-organized magnetic nanoparticles by selective cobalt silicidation
Keywords: 81.16.-c; 81.16.âc; 81.07.âb; 68.55.âa; 75.75.+a; Nanoparticles; Self-organization; Magnetism;
Photo-conversion and evolution of one-dimensional Cu nanoparticles under femtosecond laser irradiation
Keywords: 81.16.-c; 81.16.âc; 52.38.âr; 68.65.âk; 61.46.Km; 62.23.Hj; Metal nanowire; Ultrashort pulse laser; Nucleation growth process; Polarization;
Multi-scale hybrid numerical simulation of the growth of high-aspect-ratio nanostructures
Keywords: 81.16.-c; 07.05.Tp; 52.65.ây; 81.07.âb; 81.16.âc; 52.77.âj; Multi-scale hybrid simulations; Nanostructures; Plasma; Physical vapour deposition; Carbon nanotubes;
The role of fluid flow and convective steering during the assembly of colloidal crystals
Keywords: 81.16.-c; 47.11.âj; 47.15.Gâ; 47.15.âx; 47.55.Pâ; 81.10.âh; 81.16.âc; 82.70.Dd; A1. Computer simulation; A1. Convection; A1. Crystal structure; A1. Fluid flow; A3. Convective assembly; B1. Nanomaterials; B1. Colloidal crystals;
X-ray photoelectron spectroscopy investigations of Si in non-stoichiometric SiNx LPCVD multilayered coatings
Keywords: 81.16.-c; 61.46.Hk; 81.16.âc; Nano crystals; Si;
Localization of the electromagnetic field in the vicinity of gold nanoparticles: Surface modification of different substrates
Keywords: 81.16.-c; 81.16.âc; 81.65.Cf; 52.38.Mf; Plasmons; Gold nanoparticles; Femtosecond laser nanostructuring;
TEM study of annealed Pt nanostructures grown by electron beam-induced deposition
Keywords: 81.16.-c; 81.16.âc; 79.20.Uv; 81.07.Bc; Nanocrystalline materials; Transmission electron microscopy; Nanoscale materials and structures; Fabrication and characterization;
Enhanced near field mediated nanohole fabrication on silicon substrate by femtosecond laser pulse
Keywords: 81.16.-c; 81.16.âc; 81.65.Cf; 52.38.Mf; 36.40.Gk; Nanostructuring; Plasmons; Gold nanoparticles; Femtosecond laser processing;
Using defined structures on very thin foils for characterizing AFM tips
Keywords: 81.16.-c; 82.37.Gk; 81.16.âc; 81.07.Nb; 42.30.âd; 07.05.Pj; Nanomeasuring; AFM; FIB; Thin film; Foil; Tip reconstruction; Tip geometry;
Proposed strategy to sort semiconducting nanotubes by band-gap
Keywords: 81.16.-c; 81.07.De; 81.16.âc; Semiconducting nanotubes; Sorting process;
Crystallization of amorphous SiC and superhardness effect in TiN/SiC nanomultilayers
Keywords: 81.16.-c; 68.65.Ac; 81.16.âc; 68.35.Rh; 68.55.âa; 61.50.âf; 62.25.+g; TiN/SiC nanomultilayers; Crystallization; Epitaxial growth; Superhardness effect;
Growth of ferroelectric BLT and Pt nanotubes for semiconductor memories
Keywords: 81.16.-c; 81.07.Bc; 81.05.Dz; 81.16.âc; 81.15.Gh; A1. Anodization; B1. Blt; B1. Nanotube; B1. Porous alumina; B1. Pt; B2. Ferroelectric;
Growth of ZnO nanostructures in a chemical vapor deposition process
Keywords: 81.16.-c; 81.07.Bc; 81.05.Dz; 81.16.âc; 81.15.Gh; 71.35.Cc; A3. Metalorganic chemical vapor deposition; B1. Nanomaterials; B2. Semiconducting II-VI materials;
Interface study of ion irradiated Cu/Ni/Cu(0Â 0Â 2)/Si magnetic thin film by X-ray reflectivity
Keywords: 81.16.-c; 75.50.Cc; 75.75.+a; 81.16.âc; Ion irradiation; Ni/Cu; Perpendicular magnetism;
Optical effects in silica glass during implantation of 60Â keV Cuâ ions
Keywords: 81.16.-c; 61.46.+w; 78.67.ân; 81.07.Bc; 81.16.âc; Heavy-ion implantation; Metal nanoparticles; Silica glass; In situ optical transmission; Ion-induced photon emission;
Dependence on substrate topography of growth of nanosized dendritic structures in an electron-beam-induced deposition process
Keywords: 81.16.-c; 81.01.âb; 07.78; 81.15.Gh; 81.16.âc; Nanostructure; Dendrite; Transmission electron microscopy; Electron beam induced deposition; Nanofabrication;
Nanofabrication of tungsten supertip by electron-beam-induced deposition
Keywords: 81.16.-c; 81.15.Jj; 81.07.âb; 81.16.âc; 68.37.Lp; 79.20.Fv; Nanofabrication; Supertip; Electron-beam-induced deposition; Scanning transmission electron microscope;
The growth of thin silver nanowires bundle using RbAg4I5 crystal grain thin film and the ionic conductivity of the thin film
Keywords: 81.16.-c; 81.07.âb; 81.10.Jt; 81.16.âc; Superionic conductor; Ionic conductivity; Crystal grain thin film; Silver nanowires bundle;
Heavy-ion-induced luminescence of amorphous SiO2 during nanoparticle formation
Keywords: 81.16.-c; 61.46.+w; 78.76.ân; 81.07.Bc; 81.16.âc; Ion implantation; Metal nanoparticles; Silica glass; Ion-induced photon emission;
Single-crystalline ZnO nanobelts by RF sputtering
Keywords: 81.16.-c; 81.07.âb; 81.15.Cd; 81.16.âc; A1. Low-dimensional structures; A1. Nanostructures; A3. Physical vapor deposition processes; B1. Nanomaterials; B1. Oxides; B3. Semiconducting II-VI materials;
A novel application of the CuI thin film for preparing thin copper nanowires
Keywords: 81.16.-c; 81.07.âb; 81.10.Jt; 81.16.âc; Thin copper nanowire; CuI thin film; Cuprous ions transmitting; Whole solid condition;
Area selective formation of magnetic nanodot arrays on Si wafer by electroless deposition
Keywords: 81.16.-c; 75.50.Ss; 75.75.+a; 81.16.Be; 81.16.âc; Patterned media; Electroless deposition; Area selective formation; CoNiP alloys; Pd activation process;
Ion-track based single-channel templates for single-nanowire contacting
Keywords: 81.16.-c; 81.10.âh; 81.16.âC; 82.47.âa; 73.23.âb; Ion-track technology; Single-channel template; Single nanowire; Polycarbonate; Polyethylene terephthalate; Bismuth;
Well-aligned zinc oxide nanorods and nanowires prepared without catalyst
Keywords: 81.16.-c; 81.07.âb; 81.16.Dn; 81.16.âc; A1. Characterization; A3. Thermal evaporation method; B1. Nanowire; B1. Nanorod; B1. ZnO; B2. Oxide semiconducting materials;
Formation and phase transformation of selenium nanowire arrays in anodic porous alumina templates
Keywords: 81.16.-c; 81.16.âc; 61.46.+w; 61.72.Ff; 68.37.âd; A1. Transmission electron microscopy nanostructures; A2. Growth from solutions; B1. Nanowires;
Characterization of nanometer-sized dendritic form structures fabricated on insulator substrates with an electron-beam-induced deposition in a TEM
Keywords: 81.16.-c; 81.01.âb; 07.78; 81.15.Gh; 81.16.âc; Electron-beam-induced deposition; TEM; Nanostructure; Dendrite; Nanofabrication;
Transport of ions and biomolecules through single asymmetric nanopores in polymer films
Keywords: 81.16.-c; 81.16.âc; 81.07.âb; 61.82.Pv; 05.60.âk; Nanopores; Ion channels; Transport processes; DNA detection;
Micromagnetic studies of cobalt microbars fabricated by nanoimprint lithography and electrodeposition
Keywords: 81.16.-c; 75.50.Cc; 75.75.+a; 81.16.âc; Electrodeposited cobalt; Magnetic microbar; Magnetic vortex; Magnetization reversal; Magnetic force microscopy; Vibrating sample magnetometry; Micromagnetic modeling;