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New trends in instrumental design for surface plasmon resonance-based biosensors.Tailored SERS substrates obtained with cathodic arc plasma ion implantation of gold nanoparticles into a polymer matrix.Individual Template-Stripped Conductive Gold Pyramids for Tip-Enhanced Dielectrophoresis.Fabrication and characterization of flexible and tunable plasmonic nanostructuresTemplate-stripped smooth Ag nanohole arrays with silica shells for surface plasmon resonance biosensing.Light-emitting diodes enhanced by localized surface plasmon resonanceBroadband Metallic Planar Microlenses in an Array: the Focusing Coupling Effect.Optical properties of tipless gold nanopyramids.Nanoparticle SERS substrates with 3D Raman-active volumes.Nanomanipulation using near field photonics.Chemically functionalized surface patterning.Surface plasmon resonance imaging for nucleic acid detection.Plasmonic nanostructures for surface enhanced spectroscopic methods.Nanoplasmonic sensors for biointerfacial science.Outstanding surface plasmon resonance performance enabled by templated oxide gratings.DNA-directed gold nanodimers with tunable sizes and interparticle distances and their surface plasmonic properties.Controlled positioning of analytes and cells on a plasmonic platform for glycan sensing using surface enhanced Raman spectroscopy.Nanostructured plasmonic metapixels.Real-time label-free surface plasmon resonance biosensing with gold nanohole arrays fabricated by nanoimprint lithography.Plasmonic focusing in rod-sheath heteronanostructures.Broadband plasmonic microlenses based on patches of nanoholes.Laser implantation of plasmonic nanostructures into glass.A portable, benchtop photolithography system based on a solid-state light source.Pitch-tunable size reduction patterning with a temperature-memory polymer.Long-range surface plasmon resonance and surface-enhanced Raman scattering on X-shaped gold plasmonic nanohole arrays.High Figure of Merit (FOM) of Bragg Modes in Au-Coated Nanodisk Arrays for Plasmonic Sensing.Enhanced extraordinary optical transmission (EOT) through arrays of bridged nanohole pairs and their sensing applications.Modeling light-induced charge transfer dynamics across a metal-molecule-metal junction: bridging classical electrodynamics and quantum dynamics.Matrices pattern using FIB; 'Out-of-the-box' way of thinking.M-shaped grating by nanoimprinting: a replicable, large-area, highly active plasmonic surface-enhanced Raman scattering substrate with nanogaps.Physics Models of Plasmonics: Single Nanoparticle, Complex Single Nanoparticle, Nanodimer, and Single Nanoparticle over Metallic Thin Film.Simulated Optical Properties of Gold Nanocubes and Nanobars by Discrete Dipole ApproximationPlasmonic Modes and Optical Properties of Gold and Silver Ellipsoidal Nanoparticles by the Discrete Dipole ApproximationUltra-Sensitive Colorimetric Plasmonic Sensing and Microfluidics for Biofluid Diagnostics Using Nanohole ArrayNanopatterning Gold by Templated Solid State Dewetting on the Silica Warp and Weft of Diatoms
P2860
Q30471441-BCBEBD95-B18B-4A43-8148-6810296AFB27Q34123291-8DEE1BBE-CDD0-4F11-9452-D05F528E736BQ34732103-528CB1AA-A06B-4174-854B-C97887090043Q35057149-ECEFB8FF-BBC2-410C-9CFA-F8EE8E97EC39Q35177915-805BA292-E34E-4F5A-8BD8-60528F4A46A2Q35536696-CDAF5826-ACE7-4880-A4C9-313115A63AE1Q36626159-C3606586-CFBF-4703-8C82-B44B0386144EQ36785122-D6EB62A5-859D-443E-A1BA-C9A4370B4584Q37128338-A80D4F99-9077-4FD6-9DC1-E492E92F3DA2Q37829644-0D47B324-62A3-4090-8652-CB67614C6206Q37890336-686A26BD-A26B-4B9A-93AF-B9A87B32FB44Q38063097-E15F70A9-144A-4A93-BC63-B9637550E244Q38694318-837F6ECD-4A00-4E06-BB8C-D0107FD6EB46Q38734207-798A281E-22C4-463E-9221-8F894FEA19D3Q39316216-C54E439D-C4C8-40F5-A55A-4D86F4EDA186Q39468825-89530BAE-FBE0-4D6A-A911-70CA6F83B4C8Q41077228-1516696A-110D-4255-8300-1FC608F79CF1Q41353678-3E8137F3-C019-4525-9028-6D074FDE12CCQ41810350-F2AF403D-0316-403F-96AE-2C2F5AF5A8ABQ41879320-BF4776D3-C521-48BD-BB2C-9EFEE03E07E0Q42409844-713DACF8-6025-4E5C-A07B-5031CF1EF588Q44501931-BC699CB0-BE23-4DEC-BCAA-058BA407F727Q45304251-375D101C-FE4D-421A-8BE0-CADEE17412EEQ47284064-3956ABEE-D430-416B-BE2D-4A9A779F9367Q47759030-26139976-E259-40B1-BB79-8C8DC3F6C9DFQ47762885-BA8CDA0E-F1C6-4DDC-A860-02AE86F50621Q50469685-6740F8C6-BE2D-4A29-BB7A-E2BBE16E0A60Q50996020-86F7A07B-B7DB-42EA-8B15-574EE8EB7A72Q53551486-E3D2C36F-B684-4B62-8C5F-C599F903C3DBQ53590592-A37C49A4-826A-4C6D-9748-240DAC97FDA7Q54949540-01EFDD89-8AF6-444A-BD17-B766D2F6D3FDQ58909510-EB43E497-6F94-4750-B0DF-264187ED04B2Q58909811-6104F443-C1EA-47D5-BF0D-4FC67DD5A349Q59113487-878E62A9-D9BE-498B-B092-7B46A8F6ABB7Q59128420-0D8DC9F1-912D-4661-A7E5-27E49D628E38
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on January 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Nanofabrication of plasmonic structures.
@en
Nanofabrication of plasmonic structures.
@nl
type
label
Nanofabrication of plasmonic structures.
@en
Nanofabrication of plasmonic structures.
@nl
prefLabel
Nanofabrication of plasmonic structures.
@en
Nanofabrication of plasmonic structures.
@nl
P2093
P1476
Nanofabrication of plasmonic structures
@en
P2093
Jeunghoon Lee
Min Hyung Lee
Warefta Hasan
P304
P356
10.1146/ANNUREV.PHYSCHEM.040808.090352
P577
2009-01-01T00:00:00Z