Progress in plasmonic engineering of surface-enhanced Raman-scattering substrates toward ultra-trace analysis.
about
Chemically Roughened Solid Silver: A Simple, Robust and Broadband SERS SubstrateSpectral Characterization and Intracellular Detection of Surface-Enhanced Raman Scattering (SERS)-Encoded Plasmonic Gold NanostarsSE(R)RS devices fabricated by a laser electrodispersion method.Controlling the synthesis and assembly of silver nanostructures for plasmonic applications.Plasmonic properties of triangle-shaped silver trimers selectively fabricated by near-field photo-reduction using an apertured cantilever for an atomic force microscope.Microlandscaping of Au nanoparticles on few-layer MoS2 films for chemical sensing.Plasmonic core-shell nanoparticles for SERS detection of the pesticide thiram: size- and shape-dependent Raman enhancement.A rapid method to authenticate vegetable oils through surface-enhanced Raman scattering.Formation Regularities of Plasmonic Silver Nanostructures on Porous Silicon for Effective Surface-Enhanced Raman ScatteringSurface enhanced optical spectroscopies for bioanalysis.Plasmonic nanoprobes for intracellular sensing and imaging.Simple SERS substrates: powerful, portable, and full of potential.Hybrid nanostructures for SERS: materials development and chemical detection.Advances in explosives analysis--part II: photon and neutron methods.Nanosensors for early cancer detection and for therapeutic drug monitoring.Additional enhancement of electric field in surface-enhanced Raman Scattering due to Fresnel mechanism.Spectroscopic Detection of Glyphosate in Water Assisted by Laser-Ablated Silver Nanoparticles.A charge-transfer surface enhanced Raman scattering model from time-dependent density functional theory calculations on a Ag10-pyridine complex.Towards low-cost flexible substrates for nanoplasmonic sensing.Large-scale fabrication of nanodimple arrays for surface-enhanced Raman scattering.Optical interference effects in the design of substrates for surface-enhanced Raman spectroscopy.A surface enhanced Raman scattering probe for highly selective and ultra sensitive detection of iodide in water and salt samples.Explosives detection in a lasing plasmon nanocavity.Intracellular delivery of top-down fabricated tunable nano-plasmonic resonators.Surface-enhanced Raman scattering detection of ammonium nitrate samples fabricated using drop-on-demand inkjet technology.Fabrication of Semiconductor ZnO Nanostructures for Versatile SERS Application.Glass nanopillar arrays with nanogap-rich silver nanoislands for highly intense surface enhanced Raman scattering.Enhanced detection of explosives by turn-on resonance Raman upon host-guest complexation in solution and the solid state.Surface-enhanced Raman imaging of cell membrane by a highly homogeneous and isotropic silver nanostructure.Far- and near-field properties of gold nanoshells studied by photoacoustic and surface-enhanced Raman spectroscopies.Ag-decorated TiO₂ nanograss for 3D SERS-active substrate with visible light self-cleaning and reactivation.A silver/graphene oxide nanocomposite film as a flexible SERS substrate for reliable quantitative analysis using high-speed spiral scanning spectrometry.Complex nanostructures synthesized from nanoparticle colloids under an external electric field.Ultrathin Carbon Film Protected Silver Nanostructures for Surface-Enhanced Raman Scattering.Surface-enhanced Raman scattering on a hierarchical structural Ag nano-crown array in different detection ways.Optofluidic SERS chip with plasmonic nanoprobes self-aligned along microfluidic channels.Ultrasensitive SERS detection of lysozyme by a target-triggering multiple cycle amplification strategy based on a gold substrate.Surface enhanced Raman spectroscopy for microfluidic pillar arrayed separation chips.Chromatographic separation and detection of target analytes from complex samples using inkjet printed SERS substrates.Triangular Elastomeric Stamps for Optical Applications: Near-Field Phase Shift Photolithography, 3D Proximity Field Patterning, Embossed Antireflective Coatings, and SERS Sensing
P2860
Q28822574-D39CD51D-EE05-4EFD-B0BB-8403605C6775Q33616899-107B2A0B-6BBE-44E8-9ECD-CC9952ABF3F4Q33956976-78C2BD48-580F-4EE8-997D-450C4B691304Q35034007-82031BCB-D673-4350-A8E9-F8BD2FED099EQ35206147-9A7A2D7A-E194-4E9D-B40D-BAAFDAA045BBQ35541532-91105C63-5363-4E33-8546-CE16301D5F23Q35544550-82FBDD48-BF24-4CE1-A69B-46E7AF2BFC87Q36700192-BBF1A74A-F0DD-4689-B605-4DADA14AE606Q36923980-0B3C656A-FC5D-408A-BCE3-0462FC8CB43BQ37903714-0D7C097F-4BD0-4E75-8806-193B2997FF45Q38105872-35B47944-EBF3-45D0-8EDF-3C83A2A40460Q38173680-B32C0562-F711-4CD9-8992-7271D59DBF54Q38470755-FEF329A8-E7EB-4266-A768-C26B86E347CAQ38601917-7C9AA62E-C09C-455F-A72E-217E41B605A7Q38647614-CEC47880-1EEB-453A-8A82-C5649DD00657Q42063360-59B288FD-1459-4389-B22A-4ACAF2B7A0B7Q42218624-06177876-6B38-4B46-AB44-294FE61B29C7Q43042934-FD5AFF93-818B-4455-9181-75C2894CD428Q43817178-21D3C942-23AE-49B9-A345-20808E3B93C2Q44277462-9C27DB87-BB2F-4664-9CF5-E5DF6C450AC2Q45764387-BD008B3D-9832-4F2D-ABE1-9D63ACDFB57DQ46219202-D3E927FB-686A-482B-A79E-690395959DE9Q46236492-227EED24-C686-48CD-89A1-0A95F3CBE729Q46438563-6AA687CC-8365-4804-AC13-BA33CA1B6234Q46914630-E90FBD3A-F212-4DCF-8082-8B741387D932Q47113637-D451619C-601F-49C3-8166-1C41C7824EE9Q48594704-17AF29DB-81A0-45B5-965B-156CA1BA9E66Q50003194-C2E85397-BA0B-432A-8256-CBBCFC27D063Q50447441-37E30673-86B0-4C54-A1D3-3AF129188483Q50454018-C553C828-E852-4AF3-BF09-0644F51D77BBQ50489625-B06ADDB7-A5E9-44BE-AA01-00790365DD73Q50493871-5DC639D7-D3AC-4F19-AB41-1D7D0C263F67Q50514214-2554FBE1-64CE-4099-A7FB-5C60BDBA5161Q51280386-CB4BC90D-B484-489F-9359-DD172FC3780CQ51504448-6806FCAA-E31A-48ED-9D2B-3C9CB05E329CQ51523357-7119BEB1-7F70-4DD8-91CE-0D2D911B3595Q51532222-EC41A9BF-32A2-441E-B7FB-74F0CB4AFEBCQ51543366-7EC9AF8C-2468-4E9D-9953-BB9008C91C3BQ53329934-8180C2F7-B629-4E9B-AE15-8C5A3601D609Q56920865-10D2634B-0B3C-4447-BD41-DE3865D3CAD4
P2860
Progress in plasmonic engineering of surface-enhanced Raman-scattering substrates toward ultra-trace analysis.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年論文
@yue
2005年論文
@zh-hant
2005年論文
@zh-hk
2005年論文
@zh-mo
2005年論文
@zh-tw
2005年论文
@wuu
2005年论文
@zh
2005年论文
@zh-cn
name
Progress in plasmonic engineer ...... s toward ultra-trace analysis.
@ast
Progress in plasmonic engineer ...... s toward ultra-trace analysis.
@en
type
label
Progress in plasmonic engineer ...... s toward ultra-trace analysis.
@ast
Progress in plasmonic engineer ...... s toward ultra-trace analysis.
@en
prefLabel
Progress in plasmonic engineer ...... s toward ultra-trace analysis.
@ast
Progress in plasmonic engineer ...... s toward ultra-trace analysis.
@en
P1476
Progress in plasmonic engineer ...... s toward ultra-trace analysis.
@en
P2093
David S Moore
Gary A Baker
P2888
P304
P356
10.1007/S00216-005-3353-7
P407
P577
2005-07-28T00:00:00Z