about
Applications of Hyperbolic Metamaterial SubstratesSuper-resolution fluorescence microscopyLevel of holographic noise in interferometryMagnifying perfect lens and superlens design by coordinate transformationBackward spoof surface wave in plasmonic metamaterial of ultrathin metallic structureSuper-resolution imaging using a three-dimensional metamaterials nanolensMetamaterials and imagingDielectric Optical-Controllable Magnifying Lens by Nonlinear Negative Refraction.Experimental demonstration of a non-resonant hyperlens in the visible spectral range.Self-assembled tunable photonic hyper-crystals.Cryo-fluorescence microscopy facilitates correlations between light and cryo-electron microscopy and reduces the rate of photobleaching.Tunable Terahertz Deep Subwavelength Imaging Based on a Graphene MonolayerDetection of microorganisms using terahertz metamaterials.Optical virtual imaging at 50 nm lateral resolution with a white-light nanoscope.Shape-controllable microlens arrays via direct transfer of photocurable polymer droplets.Nanoscale probing of thermal, stress, and optical fields under near-field laser heating.Circuits with light at nanoscales: optical nanocircuits inspired by metamaterials.Achieving planar plasmonic subwavelength resolution using alternately arranged insulator-metal and insulator-insulator-metal composite structures.Extraordinary sensitivity enhancement by metasurfaces in terahertz detection of antibiotics.Blue shift of spontaneous emission in hyperbolic metamaterialSubdiffractional focusing and guiding of polaritonic rays in a natural hyperbolic materialLens-based fluorescence nanoscopy.Metamaterials application in sensing.Two-dimensional imaging in hyperbolic media-the role of field components and ordinary waves.Non-local Optical Topological Transitions and Critical States in Electromagnetic Metamaterials.Spectral contrast imaging microscopy.Omnidirectional optical attractor in structured gap-surface plasmon waveguide.Dual band metamaterial perfect absorber based on artificial dielectric "molecules"Shaping 3D Path of Electromagnetic Waves Using Gradient-Refractive-Index Metamaterials.Super-resolution biological microscopy using virtual imaging by a microsphere nanoscope.Nanophotonics: bright future for hyperbolic chips.Hyperbolic metamaterials: fundamentals and applications.Evolutionary optimization of compact dielectric lens for farfield sub-wavelength imagingWide-field extended-resolution fluorescence microscopy with standing surface-plasmon-resonance waves.Fine tuning and MOND in a metamaterial "multiverse".Superoscillations without sidebands: power-efficient sub-diffraction imaging with propagating waves.Optical microscopy beyond the diffraction limit.Hyperbolic-polaritons-enabled dark-field lens for sensitive detection.Electro-Optic Effects in Colloidal Dispersion of Metal Nano-Rods in Dielectric FluidQuantum mechanism of light transmission by the intermediate filaments in some specialized optically transparent cells.
P2860
Q21285064-096F60C7-0DC6-441F-88F1-F63134C52323Q24630861-6CDF6BF2-DA2E-4E8E-ABE2-618D3E10269FQ27335675-2F0576F4-D32A-4EC1-AA77-8B93F14CB3A8Q27342405-5CDBA6BC-74C6-4FA4-9E80-1D301E8220E0Q27350551-3CCDAC1D-78BF-4858-9D5C-1F5971D5DB8BQ30048096-CF85BE8B-B95E-45B5-9383-3D873898430BQ30363773-0D18AAB0-D8E6-420D-BF65-83EDD3BD8262Q30407158-1E4EA865-0D8C-422F-B7E7-3C2220476694Q30409025-69ADA1DD-3796-4D37-A1A2-177FD40FF7FFQ30583770-66A4BE33-C831-4116-873C-A9265C7784AAQ33298442-B8DBA4B7-D040-4FD3-A555-1891DD35AA9FQ33551678-543DBC26-B970-4F2D-9F95-0A132442BEE4Q33620533-AFC63BC8-7F6E-4D39-887C-6CE1D86BB16DQ33833489-153C4805-DF61-4053-A9D3-4453AC9DD1D3Q34184055-CF05561F-46BB-4AF0-BED3-5FC9F3387D6DQ34650251-4D48C027-3607-4EDA-917C-32CCEDC37E7AQ34691548-652F098A-EB01-4747-80B7-9C2FDA638250Q35004023-4EB2BB4E-D184-413E-AB0D-6D609C8D3CAEQ35133983-BE93DE77-7A39-4577-B543-4CB7E7DED1DEQ35193641-B01EF397-375F-4274-B7D4-66100EEF874DQ35574829-AC176934-391B-465C-8C1A-77C8BA2C1F2FQ35638827-825F114C-F27C-4B76-9193-F2A20EFF5507Q36036955-F91B234B-6F7F-4E5D-B2BA-6DBD3DE4C553Q36346416-112FB3B4-02A0-4ADA-92E6-9399E4D733CEQ36376039-AA8D6FD7-63F5-4204-839F-CCF8093DFB8CQ36579909-841935E8-F28E-47AA-8968-C1665BE85A1EQ36713629-C8180761-A3E4-44D7-A908-65EE89FFAA83Q37089502-965DC3D9-9E62-47AB-93AD-95397F90F0F1Q37423132-6D1FB602-9DE7-4012-A420-124DFAD9EB9BQ38986260-50B52DE5-1C04-4DD2-A0E6-70E79F8551C1Q38997045-FD2B0D1F-1493-4039-95C7-D12A70A039FAQ39132848-86085D97-DF92-478C-A024-1C40B172EF59Q41220689-CFADDBCD-88F7-40C2-8EBF-70BF1B2AAC13Q41241407-84E2F00D-89EF-4613-A12F-0019FA43AC9EQ41388301-BA475B72-5D0B-4E22-A08F-CB791FFCCE90Q41768565-DC13C840-3EC8-465D-9872-FCDF450ED786Q41895083-D8AB32C7-B5D1-4478-84AB-5353A6CD7356Q41921846-1389526D-0302-44F1-BFC6-9BB0F5B1C59EQ42085097-F1301779-2450-4F48-9DF9-28EA26EBC1EBQ42110345-DBBFE538-1687-4A74-BE29-26904C94C4FD
P2860
description
2007 nî lūn-bûn
@nan
2007 թուականի Մարտին հրատարակուած գիտական յօդուած
@hyw
2007 թվականի մարտին հրատարակված գիտական հոդված
@hy
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
name
Magnifying superlens in the visible frequency range
@ast
Magnifying superlens in the visible frequency range
@en
Magnifying superlens in the visible frequency range
@nl
type
label
Magnifying superlens in the visible frequency range
@ast
Magnifying superlens in the visible frequency range
@en
Magnifying superlens in the visible frequency range
@nl
prefLabel
Magnifying superlens in the visible frequency range
@ast
Magnifying superlens in the visible frequency range
@en
Magnifying superlens in the visible frequency range
@nl
P3181
P356
P1433
P1476
Magnifying superlens in the visible frequency range
@en
P2093
Christopher C Davis
Yu-Ju Hung
P304
P3181
P356
10.1126/SCIENCE.1138746
P407
P577
2007-03-01T00:00:00Z
P5875
P698
P818
physics/0610230