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Opto-electro-fluidics and tip coax conical surface plasmons
Touvia Miloh
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Corresponding author for this work
School of Mechanical Engineering
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Article
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peer-review
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Scopus citations
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Keyphrases
Coaxing
100%
Nanoparticles
100%
Surface Plasmon
100%
Fluidics
100%
Field Enhancement
100%
Conical Surface
100%
Polarizable
50%
Dielectric
50%
Convection
50%
Aqueous Phase
50%
Electrolyte
50%
Dispersion Relation
50%
Dielectrophoretic Force
50%
Electromagnetic Energy
50%
Near-field
50%
Optical Tweezers
50%
Visible-infrared
50%
Near-infrared Spectrum
50%
Surface Plasmon Polaritons
50%
Thermo
50%
Solute
50%
Heat Conduction
50%
Operating Conditions
50%
Induced Flow
50%
Flow Distribution
50%
Singular Behavior
50%
Plasmonic Field
50%
Metastructure
50%
Low Input
50%
Joule Heating Effect
50%
Metallic Structure
50%
Nanofocusing
50%
Energy Enhancement
50%
Noble Metal Surfaces
50%
Microvortex
50%
Vorticity Distribution
50%
Apex Angle
50%
Conical Tip
50%
Engineering
Fluidics
100%
Surface Plasmon
100%
Nanoparticle
66%
Field Enhancement
66%
Dielectrics
33%
Energy Engineering
33%
Optical Tweezers
33%
Dispersion Relation
33%
Vorticity
33%
Aqueous Phase
33%
Joule Heating Effect
33%
Metallic Structure
33%
Including Mean
33%
Field Expression
33%
Material Science
Fluidics
100%
Surface Plasmon
100%
Nanoparticle
66%
Dielectric Material
33%
Metal Surface
33%
Optical Tweezer
33%
Chemical Engineering
Nanoparticle
100%
Joule Heating
50%
Heat Conduction
50%
Precious Metal
50%