about
sameAs
Applications of Hyperbolic Metamaterial SubstratesExperiments on Seismic Metamaterials: Molding Surface WavesTransformation electronics: Tailoring the effective mass of electronsTunable terahertz metamaterials with negative permeabilityAcoustic metamaterials: From local resonances to broad horizonsFrom Animaculum to single molecules: 300 years of the light microscope25th anniversary article: ordered polymer structures for the engineering of photons and phonons.Forests as a natural seismic metamaterial: Rayleigh wave bandgaps induced by local resonances.Inverse Doppler Effects in Broadband Acoustic Metamaterials.Transformation seismology: composite soil lenses for steering surface elastic Rayleigh waves.Adiabatic far-field sub-diffraction imaging.Observation of the Zero Doppler EffectNonlinear metamaterials for holographyComplementary Media Invisibility Cloak that Cloaks Objects at a Distance Outside the Cloaking ShellTransporting an Image through a Subwavelength HoleEnhanced localization of Dyakonov-like surface waves in left-handed materialsMagnetic Metamaterials at Telecommunication and Visible FrequenciesDirect observation of negative-index microwave surface wavesMagnifying perfect lens and superlens design by coordinate transformationLeft-Handed Materials Do Not Make a Perfect LensWave propagation in media having negative permittivity and permeabilityDynamical Electric and Magnetic Metamaterial Response at Terahertz FrequenciesMidinfrared Resonant Magnetic Nanostructures Exhibiting a Negative PermeabilityPower Propagation in Homogeneous Isotropic Frequency-Dispersive Left-Handed MediaTerahertz Response of a Microfabricated Rod–Split-Ring-Resonator Electromagnetic MetamaterialBackward spoof surface wave in plasmonic metamaterial of ultrathin metallic structureSuperprism phenomenon in three-dimensional macroporous polymer photonic crystalsSplit-ring resonators and localized modesScattering Lens Resolves Sub-100 nm Structures with Visible LightAnisotropic Metamaterials for Full Control of Acoustic WavesTotal Negative Refraction in Real Crystals for Ballistic Electrons and LightNear-Perfect Imaging in a Focusing System Based on a Left-Handed-Material PlateOvercoming the Diffraction Limit with a Planar Left-Handed Transmission-Line LensIntense Nonlinear Magnetic Dipole Radiation at Optical Frequencies: Molecular Scattering in a Dielectric LiquidMetamaterials: Ideal focusOptical negative refraction in bulk metamaterials of nanowiresPhysics. Negative refraction for electrons?Optical properties of drug metabolites in latent fingermarksTunable graphene-based mid-infrared plasmonic wide-angle narrowband perfect absorberElectromagnetic resonances in individual and coupled split-ring resonators
P2860
Q21285064-FA874330-EB96-4E26-A3DD-4C534F25A902Q21706466-C4F4E6BC-16F7-4928-83CA-6221CDCBC8E2Q21708333-59523DF7-845C-4542-B5B6-5CF28F962BE8Q21708369-CDE483CA-59C5-4A18-8F5D-92EDE60ED402Q26765066-11345B3A-C49D-4531-9141-5D43098F90CBQ26829384-E94CF5F9-C16B-4436-822D-80D295FF0DFAQ27011228-A23CD5A8-BAD8-4B7D-B65B-F7A7E40C77BEQ27301851-8A830723-DF75-410E-A2F1-C875FD06D701Q27313894-45317173-7EDC-4453-91EB-8F45B97C2EDDQ27317522-E06C3A28-0F7C-49EA-B61B-63BDD2BA591CQ27323301-4B61270A-5CD2-440C-9785-145E8313E469Q27324009-233D98C2-C2C5-442C-AB98-F5EBC03988D4Q27332218-A878D1C2-050C-435C-8037-9901838853EEQ27336260-89F76A05-97FF-4B77-BB80-BB83FD6D24BAQ27339214-4448D0FF-E52C-482B-9403-02A7EE71C867Q27339249-CDAB094A-74B1-4493-A10E-7791C52E5F2DQ27339410-76895B13-B210-49FD-85DD-2672E2ED1211Q27342124-4A0F0F99-598D-450C-9FF3-6CF88C362BBBQ27342405-7A455C89-52C7-4DCC-87BC-88FBC8584BB9Q27346359-709E70AD-FAE4-4D12-90A1-7321785657EDQ27346442-D4E3CB0B-1018-450B-A2D4-A100A504CD29Q27346652-1EFA5163-E751-42C0-9E97-2B66A03A9FFAQ27350365-D12B4194-5664-4E83-805C-E99918CCC2B5Q27350410-A66D63EC-B492-46E4-AE62-53F219F044F5Q27350434-B03B471D-4CBF-4A68-A658-0A75EF5ABDDCQ27350551-AD96279D-369E-4AB7-B54F-E32C2DF2A750Q27440523-20580D4F-04A0-48B8-850B-D225009327BEQ27440587-73600E4A-C4D5-4AF3-8F59-428D25CD7E01Q27448620-F694076E-4F1D-4E31-B40B-C2609AF1B614Q27448658-6175C96F-10BA-4E45-A875-FC2B6A0646F1Q27450952-78463394-46ED-4A06-8896-778C736DF612Q27451318-7DFBBFEE-4BEF-4AD2-82E1-A01401038F6BQ27451509-BCC18405-3F4C-46FD-9DD7-14E196F98874Q27454485-A95A3963-7F06-4A24-B05C-B8F119941BB3Q28246701-FF852CFA-F6C1-4639-9E1B-DF0DB276F54BQ28290889-FCD7C6DE-A87E-4569-A761-F22B306C1F7FQ28290963-72493FD3-E9B2-44B5-AB07-68C76FDE0319Q28601469-7A210E1B-2A9C-4F84-B85C-48E969CE0C2EQ28821431-9691A0CD-7FE9-483C-B1AA-D971561ADC42Q29011595-AE72E857-8C2E-481F-89C0-70BA8211CBD1
P2860
description
2000 nî lūn-bûn
@nan
2000 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2000 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
2000年の論文
@ja
2000年論文
@yue
2000年論文
@zh-hant
2000年論文
@zh-hk
2000年論文
@zh-mo
2000年論文
@zh-tw
2000年论文
@wuu
name
Negative refraction makes a perfect lens
@ast
Negative refraction makes a perfect lens
@en
Negative refraction makes a perfect lens
@en-gb
Negative refraction makes a perfect lens
@nl
type
label
Negative refraction makes a perfect lens
@ast
Negative refraction makes a perfect lens
@en
Negative refraction makes a perfect lens
@en-gb
Negative refraction makes a perfect lens
@nl
prefLabel
Negative refraction makes a perfect lens
@ast
Negative refraction makes a perfect lens
@en
Negative refraction makes a perfect lens
@en-gb
Negative refraction makes a perfect lens
@nl
P3181
P1476
Negative Refraction Makes a Perfect Lens
@en
P2093
J. B. Pendry
P304
P3181
P356
10.1103/PHYSREVLETT.85.3966
P407
P577
2000-10-01T00:00:00Z
2000-10-30T00:00:00Z