ライフサイエンスコーパス: plasmonic

1 including nonlinear optics, spintronics and plasmonics.

2 derpins the fundamentals and applications of plasmonics.

3 damental studies and applications in quantum plasmonics.

4 We present an all-plasmonic 116-gigabits per second electro-optical modula

5 in 3D nanoporous graphene disclosing strong plasmonic absorptions tunable from terahertz to mid-infr

6 rmediate through plasmonic effects, in which plasmonic Ag-Pt bimetallic nanocages were synthesized wi

7 ns might no longer be applicable and quantum plasmonic and atomistic effects could become relevant.

8 Despite efforts to combine plasmonic and catalytic metals, the physical mechanisms

9 ances of incident electromagnetic waves with plasmonic and excitonic states typical for metals and se

10 this work and the ability to switch between plasmonic and fluorescent semiconductor nanocrystals mig

11 jor challenges to the widespread adoption of plasmonic and nano-optical devices in real-life applicat

12 In both cases, resonant plasmonic and nanophotonic structures have been successf

13 phene emerged as an outstanding material for plasmonic and photonic applications due to its charge-de

14 ight-induced processes such as nano-enhanced plasmonics and catalysis, light harvesting, or phase tra

15 cations through substrate development for UV plasmonics and short-distance capture strategies for opt

16 s for fabrication of metamaterials, sensors, plasmonics, and micro/nanoelectromechanical systems.

17 absorption process of an emitter close to a plasmonic antenna is enhanced due to strong local electr

18 rter-wave plate made of anisotropic T-shaped plasmonic antennas in near-infrared wavelength range, wh

19 of the emission of single molecules close to plasmonic antennas, therefore, provides mixed informatio

20 wo mechanisms for polarization conversion by plasmonic antennas: Structural asymmetry and plasmon hyb

21 provide a platform for a variety of enhanced plasmonic applications in sensing and imaging.

22 s a detriment, has now expanded the scope of plasmonic applications to exploit the generated hot carr

23 for high quality (Q)-factor multi-functional plasmonic applications.

24 By coupling with different plasmonic array geometries, we have shown that the photo

25 ariation of the structural parameters of the plasmonic array in our experiment, we demonstrate modula

26 pontaneous emission rate in a double spacing plasmonic array structure as compared with an equal spac

27 ixture of superparamagnetic Zn0.2Fe2.8O4 and plasmonic Au nanocrystals.

28 The template for the plasmonic AuNP assembly is a bioconjugate between short

29 shape can stimulate plasmonic effects, (iii) plasmonic based nanobiosensors are to explore the effica

30 Here we report a plasmonic-based electrochemical impedance imaging techni

31 The transition from molecular to plasmonic behaviour in metal nanoparticles with increasi

32 ectroscopy has previously been used to image plasmonic behaviour in nanostructures in an electron mic

33 Here, we show how the recently demonstrated plasmonic behaviour of rhodium nanoparticles profoundly

34 l gates to fully tune the thermoelectric and plasmonic behaviour of the graphene.

35 the advancement of current state-of-the-art plasmonic biosensing technology toward single molecule l

36 Nanostructure-based plasmonic biosensors have quickly positioned themselves

37 mising for the improvement of performance of plasmonic biosensors, but conditions of implementation o

38 , we aim at unraveling the true potential of plasmonics by exploiting an enhanced native functionalit

39 nership between super-resolution imaging and plasmonics, by describing the various ways in which the

40 s, covering them to generate structures with plasmonic chirality that exhibit significantly improved

41 of this family of materials exhibit intense plasmonic chiroptical activity.

42 sent an optoelectronic switch for functional plasmonic circuits based on active control of Surface Pl

43 The plasmonic color filter-integrated perovskite solar cells

44 de higher than the performance obtained with plasmonic colorimetry and absorption spectrometry of sin

45 gnetic component is typically reduced by the plasmonic component in conventional core-shell structure

46 conferring high near-infrared absorption to plasmonic component, the hollow cavity and the pores in

47 and direct shuttling of charges in nanoscale plasmonic components across a dielectric spacer and thro

48 cle detectors, accelerators and new types of plasmonic couplers.

49 uggesting that hydration-induced microscopic plasmonic coupling between AuNPs is replicated in the ma

50 We observe strong plasmonic coupling between the spatially separated gold

51 therefore be used to improve and control the plasmonic coupling mechanism.

52 In this plasmonic design, the samples are placed on a silver-coa

53 We propose a hybrid plasmonic device consisting of a planar dielectric waveg

54 To design an optimal plasmonic device, a semianalytical model was implemented

55 l dynamics of hot electrons in an emblematic plasmonic device, the adiabatic nanofocusing surface-pla

56 the performance and functionality of passive plasmonic devices operating at optical frequencies.

57 ignificant advances made in plasmonics, most plasmonic devices suffer critically from intrinsic absor

58 ntial for developing integrated photonic and plasmonic devices.Exciton energy transfer in monolayer t

59 se as a highly functional and ultrasensitive plasmonic DNA biochip in molecular beacon fashion.

60 on of the enhancement of Raman scattering by plasmonic effects is largely determined by the propertie

61 properties like size and shape can stimulate plasmonic effects, (iii) plasmonic based nanobiosensors

62 n of undesired peroxide intermediate through plasmonic effects, in which plasmonic Ag-Pt bimetallic n

63 t where fluorescence signals are enhanced by plasmonic effects.

64 tum efficiency, several groups have explored plasmonic enhancement, so far with moderate results.

65 oscillations between two spatially separated plasmonic entities via a virtual middle state exemplify

66 More precisely, plasmonic extinction spectra and near-field enhancement

67 on of low electronic heat capacity and large plasmonic field concentration in doped graphene.

68 at this advanced stage correlate with local plasmonic field enhancements, which allows determining t

69 ong Raman enhancement due to the overlapping plasmonic fields emanating from the nearest-neighbor gol

70 ace plasmon resonance due to the coupling of plasmonic fields of adjacent nanoparticles.

71 a series of single-nanoparticle-layer (SNL) plasmonic films is fabricated.

72 es of a semiconductor across a wide range of plasmonic frequencies by varying the size of NCs and the

73 The combined superparamagnetic and plasmonic functions enable switching of the infrared tra

74 We used an integrated plasmonic gap waveguide that strongly confines light wit

75 Plasmonic gold (Au) nanotriangular arrays, functionalize

76 llenges, we developed a nanotechnology-based plasmonic gold chip for autoantibody profiling.

77 coated with a noncontinuous, nanostructured plasmonic gold film, enabling quantitative fluorescent d

78 (BSA) protein onto a silica-coated array of plasmonic gold nanodisks.

79 iting endonuclease-controlled aggregation of plasmonic gold nanoparticles (AuNPs) for label-free and

80 a novel assembly structure of near-infrared plasmonic gold nanoparticles (AuNPs), possessing both ph

81 zimuthal and elevation angles of anisotropic plasmonic gold nanorod probes in live cells.

82 higher photoacoustic signals, compared to a plasmonic gold nanorod.

83 bination of immune-checkpoint inhibition and plasmonic gold nanostar (GNS)-mediated photothermal ther

84 zation of the inner surfaces of the MTs with plasmonic gold nanostars, and conformal contact of the c

85 We developed a multiplexed assay on a plasmonic-gold platform for measuring IgG and IgA antibo

86 which is incorporated in a gated TiN/SiO2/Ag plasmonic heterostructure.

87 the accumulation of population inversion at plasmonic hot spots can be spatially modulated by the di

88 over which charge carriers transferred from plasmonic hot spots can drive chemistry.

89 idine radical anion species localized in the plasmonic hot spots of individual gold nanosphere oligom

90 the growth mechanism and a possible role of plasmonic "hot spots" within the metal nanostructures, r

91 scopy of a few molecules within each coupled plasmonic hotspot, with near thousand-fold enhancement o

92 Plasmonic hotspots generate a blinking Surface Enhanced

93 ox processes in molecules located within the plasmonic hotspots.

94 Magnetic-plasmonic hybrid nanoparticles (MPHNs) have attracted gr

95 Evidence from correlative fluorescence and plasmonic imaging shows that endocytosis of fPlas-gold f

96 We anticipate that the plasmonic imaging technique will contribute to the study

97 Our results show that plasmonics is indeed a viable path to an ultracompact, h

98 r technology and identifies situations where plasmonic lasers can have clear practical advantage.

99 antly, we find unusual scaling laws allowing plasmonic lasers to be more compact and faster with lowe

100 DFH-4T films without any additional plasmonic layer exhibit unprecedented Raman signal enhan

101 s, hydrogen generation), emissive materials (plasmonics, LEDs, biolabelling), sensors (electrochemica

102 nonthermal chemical processes that depend on plasmonic light harvesting and the transfer of nonequili

103 ls for applications in cellular recognition, plasmonics, light harvesting, model systems for membrane

104 Contrary to the state-of-the-art plasmonic logic devices, we use the phase of the wave in

105 While recent advances in plasmonic logic have witnessed the demonstration of basi

106 single-stage compared with previous works on plasmonic logic.

107 y occur in metals, but many metals have high plasmonic loss in the optical range, a main issue in cur

108 e silver films which suffer from significant plasmonic losses due to grain boundaries and rough silve

109 Yet in general, low reflectance due to plasmonic losses, and sub-optimal design schemes, have l

110 ein, we report a new class of double-layered plasmonic-magnetic vesicle assembled from Janus amphiphi

111 e scheme for building a nanoscale cascadable plasmonic majority logic gate along with a novel referen

112 r has long been known as the highest quality plasmonic material for visible and near infrared applica

113 k metallic film of indium tin oxide (ITO), a plasmonic material serving as a low-carrier-density Drud

114 New plasmonic materials are actively being searched, especia

115 properties of catalysts, battery materials, plasmonic materials, etc.

116 graphene sheet serves simultaneously as the plasmonic medium and detector.

117 and thus limited energy transfer between the plasmonic metal and the semiconductor.

118 id core-shell nanostructures in which a core plasmonic metal harvests visible-light photons can selec

119 It has been shown that photoexcitation of plasmonic metal nanoparticles (Ag, Au and Cu) can induce

120 d chemical catalysis on surfaces of strongly plasmonic metal nanoparticles.

121 ses various electron-transfer models on both plasmonic metal nanostructures and plasmonic metal/semic

122 s on both plasmonic metal nanostructures and plasmonic metal/semiconductor heterostructures.

123 mechanisms that govern energy transfer from plasmonic metals to catalytic metals remain unclear.

124 Electrostatic actuation of the plasmonic metamaterial absorber's position leads to a dy

125 plicability of surface lattice resonances in plasmonic metamaterial arrays to biosensing using standa

126 e we exploit strong chiral interactions with plasmonic metamaterials with specifically designed optic

127 Here, using plasmonic metamaterials, we demonstrate that coherent sp

128 ical cells, enabling the creation of tunable plasmonic metamaterials.

129 enues for a range of applications, including plasmonics, metamaterials, flexible electronics and bios

130 Here we demonstrate the plasmonic metapixel; which permits high reflection capab

131 Plasmonic metasurface based quarter-wave plates have bee

132 A plasmonic metasurface with an electrically tunable optic

133 Our plasmonic microarray is composed of gold nanohole sensor

134 es using Graphene which yielded an efficient plasmonic mode with low loss for Supercontinuum(SC) gene

135 omplexity and probing them at the individual plasmonic molecule level, intramolecular coupling of aco

136 However, the vibrational modes of plasmonic molecules have been virtually unexplored.

137 By designing precisely configured plasmonic molecules of varying complexity and probing th

138 rs of plasmonic nanoparticles, also known as plasmonic molecules.

139 manipulated through the configuration of the plasmonic molecules.

140 Despite the significant advances made in plasmonics, most plasmonic devices suffer critically fro

141 ted gold nanorods (henceforth referred to as plasmonic nano vectors (PNVs)) as potential carriers for

142 a new kind of light-harvesting devices using plasmonic nano-antenna gratings, that enhance the absorp

143 Polarization control using single plasmonic nanoantennas is of interest for subwavelength

144 The rational combination of plasmonic nanoantennas with active transition metal-base

145 eveals that the nanostructured material with plasmonic nanobiosensor paves a fascinating platform tow

146 of new drug nanocarriers, we propose a novel plasmonic nanocarrier grid-enhanced Raman sensor which c

147 ere we demonstrate SWCNT excitons coupled to plasmonic nanocavity arrays reaching deeply into the Pur

148 n metamaterials, nanoscale photonic devices, plasmonic nanoclusters and surface-enhanced Raman scatte

149 open new avenues for designing miniaturized plasmonic nanodevices with various applications.

150 pens the door for spectroscopic targeting of plasmonic nanodrugs and quantitative assessment of nanos

151 The plasmonic nanogrid sensor offers strong Raman enhancemen

152 Here we introduce a 22-nm spaser (plasmonic nanolaser) with the ability to serve as a supe

153 Plasmonic nanolasers are a new class of amplifiers that

154 Here, we report plasmonic nanolasers with extremely low thresholds on th

155 A novel plasmonic nanoledge device was presented to explore the

156 ation of reversibly reconfigurable colloidal plasmonic nanomaterials based on the actuation of interp

157 ntly, the topic of reversibly reconfigurable plasmonic nanomaterials has become an intensive research

158 ue ability to concentrate and scatter light, plasmonic nanomaterials have been the focus of tremendou

159 ver, the novel analytical method of using 2D plasmonic nanoparticle as a sensor to understand the pol

160 and their emission localized, are applied to plasmonic nanoparticle substrates, revealing the hidden

161 ned data can be easily extended to other non-plasmonic nanoparticle systems having similar chemical a

162 for fabricating selectively solar-absorbing plasmonic-nanoparticle-coated foils (PNFs).

163 The intra- and extracellular positioning of plasmonic nanoparticles (NPs) can dramatically alter the

164 this effect are related to the morphology of plasmonic nanoparticles and their relative distribution

165 Second, plasmonic nanoparticles are explored as image contrast a

166 izes intrinsically flat two-dimensional (2D) plasmonic nanoparticles as sensors for unveiling the mec

167 ontrolled self-assembly/disassembly of 16 nm plasmonic nanoparticles at the interface between two imm

168 Via ultraviolet-visible spectroscopy, the plasmonic nanoparticles can be used to determine the amo

169 Plasmonic nanoparticles hold great promise as photon han

170 ht the possibility of deposition/assembly of plasmonic nanoparticles onto the fibrillar constructs.

171 ibing the near-field coupling in clusters of plasmonic nanoparticles, also known as plasmonic molecul

172 theoretical results on the use of broadband plasmonic nanopatch metasurfaces comprising a gold subst

173 lasmon resonances in ultrathin subwavelength plasmonic nanoresonators are demonstrated.

174 This electrically driven plasmonic nanorod metamaterial platform can be useful fo

175 e containing an array of electrically driven plasmonic nanorods with up to 10(11) tunnel junctions pe

176 ate a new radiation protection mechanism via plasmonic nanoshielding.

177 Here, we introduce plasmonic nanospectroscopy as an experimental approach t

178 e resolved with exceptional precision by the plasmonic nanospectroscopy method, which relies on remar

179 the SERS signal of the SLG on the patterned plasmonic nanostructure for a 532 nm excitation laser wa

180 Plasmonic nanostructures boast broadly tunable optical p

181 Plasmonic nanostructures can fill this role by having th

182 he limited resonant bandwidth, most periodic plasmonic nanostructures cannot cover both fundamental e

183 The biofunctionality of these plasmonic nanostructures has been demonstrated by fluore

184 luding the concept of SERS hot spots and the plasmonic nanostructures necessary for SM detection, the

185 (ZIF-8) grown around antibodies anchored to plasmonic nanostructures serves as a protective layer to

186 Biofunctional multimodal plasmonic nanostructures suitable for multiplexed locali

187 of scanning probe microscopies by utilizing plasmonic nanostructures to confine the incident electro

188 , the development of humidity-responsive, 2D plasmonic nanostructures with switchable chromogenic pro

189 the unique optical phenomena associated with plasmonic nanostructures, the scope for use in reflectiv

190 echnique enables the formation of functional plasmonic nanostructures.

191 tromagnetic field polarization for different plasmonic nanostructures.

192 o create multiplexed hapten-biofuncionalized plasmonic nanostructures.

193 les residing in high local optical fields of plasmonic nanostructures.

194 phological control, the sensitivities of the plasmonic nanotriangular arrays are controllable, paving

195 A stacked plasmonic nanowell-nanopore biosensor strongly suppresse

196 Therefore, most previously reported plasmonic nonlinear optical processes are low in convers

197 Aluminum plasmonics offers attractive opportunities for the contr

198 ut between gold nanoparticles (AuNP) and non-plasmonic ones.

199 t the analysis of a concentric circular ring plasmonic optical antenna (POA) array using a simple lum

200 rk presents the development of an innovative plasmonic optical fiber (OF) immunosensor for the detect

201 l atomic force microscope probe coupled to a plasmonic optical tweezer.

202 ce structures consisting of phased arrays of plasmonic or dielectric nanoantennas can be used to cont

203 y non-covalent interactions not just between plasmonic particles, but between gold nanoparticles (AuN

204 Although enhanced plasmonic performance at low temperature has been predic

205 ter summarizing the current understanding of plasmonic phenomena at extremely short length scales, we

206 um based antenna-reactor heterostructures in plasmonic photocatalysis provides a sustainable route to

207 he scope of chemical reactions possible with plasmonic photocatalysis.

208 Plasmonic photoconductive antennas have great promise fo

209 dband terahertz detectors through large-area plasmonic photoconductive nano-antenna arrays.

210 First, the hybrid plasmonic-photonic crystal biosilica with three dimensio

211 Here, we introduce a plasmonic photothermal method for quantitative real-time

212 Gold nanorods (AuNRs)-assisted plasmonic photothermal therapy (AuNRs-PPTT) is a promisi

213 Our hybrid dielectric-loaded nanoridge plasmonic platform may serve as a fundamental building b

214 ility to evade high resolution from a purely plasmonic point of view.

215 on of hollow cavity between the magnetic and plasmonic portions significantly prevents the decline in

216 rticles as a dually emissive fluorescent and plasmonic probe to examine their clustering states and i

217 ned and amplified at the apex of a nanoscale plasmonic probe, meets these criteria.

218 cause the target wavelength is not part of a plasmonic process, subtractive color filtering and mirro

219 and aspect ratio that impart GNRs with their plasmonic properties also make them a source of entropy.

220 icles offers the possibility to tailor their plasmonic properties and intrinsic electromagnetic "hots

221 This doping process allows tuning of the plasmonic properties of a semiconductor across a wide ra

222 didate for numerically studying the wideband plasmonic properties of DCP media.

223 b-lattice combined with the actively tunable plasmonic properties of the Cu2Se clusters make them sui

224 y affects their optoelectronic, optical, and plasmonic properties.

225 cal (electronic and catalytic) and physical (plasmonic) properties of an atomically well-defined Pd(s

226 Plasmonics provides a possible route to overcome both th

227 n the optical range, a main issue in current plasmonic research.

228 Our results open a path for plasmonics research in previously untapped insulating an

229 tegrates transmission-mode localized surface plasmonic resonance (LSPR) into a quartz crystal microba

230 e morphology-induced, polarization-dependent plasmonic resonance and a combination of bulk and surfac

231 elucidate the nanoshielding mechanism via UV plasmonic resonance and nanotailing effects.

232 Our data indicates that the plasmonic resonance couples to optical fields at both, e

233 Here, we investigate plasmonic resonance driven enhanced scattering from micr

234 s with a 10 nm indium tin oxide film, having plasmonic resonance in the 1500 nm wavelength range, sho

235 The mechanism of this giant plasmonic resonance is well interpreted by the dispersio

236 the fluorophore excitation/emission and the plasmonic resonance of the GNR array, indicating a surfa

237 tamaterials, microwave transmission, surface plasmonic resonance, nanoantennas, and their manifested

238 dbanding of the reflectance spectra from the plasmonic resonances due to charge carriers generated fr

239 implementation of such diffractively coupled plasmonic resonances, also referred to as plasmonic surf

240 ne nanoribbons functioning as both localized plasmonic resonators and local Joule heaters upon applic

241 rising from the Larmor radiation of adjacent plasmonic resonators because their inclusion in a simple

242 such as the tunable optical, electrical, and plasmonic response make it ideally suited for applicatio

243 We characterize the terahertz (THz) magneto-plasmonic response of a cobalt-based periodic aperture a

244 Further, by leveraging the plasmonic response of AuNPs, we can rupture the microshe

245 ry of reports on quantum size effects in the plasmonic response of nanometre-sized metal particles, s

246 We have shown that the plasmonic response of the nanoarray can be tuned by the

247 Due to the collective plasmonic responses in SNL, these ultrathin 2D films dis

248 p-type transparent conductive oxides and as plasmonic semiconductors.

249 thography that enable Kretschmann-configured plasmonic sensing of bacterial toxins.

250 ation of surface plasmon resonance (SPR) for plasmonic sensing.

251 perform the relevant parameter for all other plasmonic sensor counterparts.

252 el and competitive nanoporous-graphene based plasmonic-sensors.

253 ecular beacon-like structure, we combine the plasmonic signal enhancement with a specific signal gene

254 e conversion of the electrical signal into a plasmonic signal, which is imaged optically without labe

255 oscope junction not only bears its intrinsic plasmonic signature but is also imprinted with the chara

256 minal group of a self-assembled monolayer on plasmonic silver nanoantennas, with theoretical predicti

257 To guide the design of plasmonic solar cells, theoretical investigation of core

258 e far-field by coupling with the antenna via plasmonic states, whose presence increases the local den

259 ded graphene layer to form a doubly resonant plasmonic structure.

260 achieved by means of a nanocavity formed by plasmonic structures and a distributed Bragg reflector.

261 This article presents four different plasmonic structures using Graphene which yielded an eff

262 cannot be achieved with narrow band periodic plasmonic structures.

263 cations of SERS spectroscopy: quality of the plasmonic substrate and molecule localization to the sub

264 Here, we describe and engineer plasmonic substrates based on metal-insulator-metal (MIM

265 Precisely tailored plasmonic substrates can provide a platform for a variet

266 atly diminished, thus enabling the design of plasmonic substrates with large Q factor and strong sens

267 g array on a glass surface was fabricated as plasmonic substrates, resulting in dramatically intensif

268 phonon-polaritonic hexagonal boron nitride, plasmonic super-lattices and hyperbolic meta-surfaces as

269 Three-dimensional plasmonic superlattice microcavities, made from programm

270 Here, we describe how plasmonic superlattices-finite-arrays of nanoparticles (

271 ed plasmonic resonances, also referred to as plasmonic surface lattice resonances (PSLR), are not alw

272 Sb2Te5 (GST)) allows for designing a tunable plasmonic switch for optical communication applications

273 e possibility of making electrically tunable plasmonic switches and optical memory elements by exploi

274 his tuning and demonstrates a liquid crystal-plasmonic system that covers the full RGB colour basis s

275 to spectrally decouple the emission from the plasmonic system, leaving the absorption strongly resona

276 The emission, if resonant with the plasmonic system, re-radiates to the far-field by coupli

277 Here, using gold nanorods as model plasmonic systems, InAs quantum dots (QDs) embedded in a

278 nic materials, as is typically done in other plasmonic systems, our device converts the natural decay

279 talysis within optically confined near-field plasmonic systems.

280 , we confirm the extraordinary capability of plasmonic tapers to generate hot carriers by slowing dow

281 The solventless nature of the plasmonic-TDD method enabled the nonenzymatic on-surface

282 The advantages of this novel plasmonic-TDD method include short reaction times (<30 s

283 ple experiments confirmed the ability of the plasmonic-TDD method to induce both C-cleavage and D-cle

284 The high spatial specificity of the plasmonic-TDD method was demonstrated by using a mask to

285 In the plasmonic-TDD setup the sample is coated with Au-NPs and

286 r plasmonic thermal decomposition/digestion (plasmonic-TDD) method incorporates a continuous wave (CW

287 @Au NPs can be regarded as an ideal magnetic-plasmonic theranostic platform for magnetic resonance/ph

288 This photothermal process or plasmonic thermal decomposition/digestion (plasmonic-TDD

289 We have developed a plasmonic thermal history indicator (THI) taking advanta

290 , outperforming those obtained by thermal or plasmonic thermal treatment.

291 ttering with weakened backward scattering in plasmonic thin film solar cells.

292 e prediction is remarkably advantageous over plasmonic tunable metasurfaces in the power-efficiency a

293 Illumination of the plasmonic tweezer with CPL exerts a force on the microsc

294 In this work, we present a novel plasmonic tweezers based on metahologram.

295 The work illustrates the potential of such plasmonic tweezers for further development in lab-on-a-c

296 The emerging development of the hybrid plasmonic waveguide has recently received significant at

297 strate, a hybrid dielectric-loaded nanoridge plasmonic waveguide is formed.

298 nsional light-emitting materials with planar plasmonic waveguides and offers great potential for deve

299 t the self-assembled nanoparticles behave as plasmonic waveguides.

300 rid plasmon polariton with dielectric-loaded plasmonic waveguiding.