ライフサイエンスコーパス: plasmonic

1 ttention due to promising applications in UV plasmonics.

2 s has emerged as an important alternative to plasmonics.

3 ment that is difficult to achieve with metal plasmonics.

4 faces(1,2), holography(3), optophoretics(4), plasmonics(5) or lenticular lenslets(6) can create 3D vi

5 n response to thermal gradients generated by plasmonic absorbance of NIR irradiation, with velocities

6 As temperature rises, plasmonic absorption of PNIPAM-capped Au NPs red-shifts

7 o localized photothermal heating provided by plasmonic absorption of waveguided light and resulting i

8 Illumination of a voltage-biased plasmonic Ag cathode during CO(2) reduction results in a

9 Bifunctional nanocrystals with integrated plasmonic and catalytic activities hold great promise fo

10 A variety of alternative plasmonic and dielectric material platforms-among them n

11 Consequently, the interest in chiral plasmonic and hybrid systems has continually grown in re

12 ing new opportunities to combine dielectric, plasmonic and magnetic metamaterials in a single platfor

13 with the electronic properties of metals for plasmonic and meta-material applications.

14 Recently, solid-state plasmonic and nanopore structures have been integrated w

15 or quantum dots and nanoplatelets, and metal plasmonic and reticular framework nanoparticles.

16 h interest for various applications, such as plasmonics and catalysis.

17 niques, the extraordinary epsilon-near-zero, plasmonic, and low/high-index characteristics of Bi:Sb:T

18 rostructures have applications in catalysis, plasmonics, and electronics.

19 SWCNTs for applications in nanoelectronics, plasmonics, and thermoelectricity.

20 The coupled magnetic and plasmonic anisotropy allows control of the rod orientati

21 By coupling magnetic and plasmonic anisotropy, the plasmonic excitation of the hy

22 hybrid nanorods integrated with magnetic and plasmonic anisotropy.

23 ), a polymer-coated gold nanorod acting as a plasmonic antenna and biotin as a high-affinity biorecog

24 es in one device, by efficient coupling of a plasmonic antenna to hyperbolic phonon-polaritons in hex

25 he most frequently used materials in current plasmonic applications, are stabilized in different appl

26 eiving increasing attention for photonic and plasmonic applications, we grew nanostructured porous si

27 lity in various systems, including molecular-plasmonic assemblies, chiral plasmonic nanostructures, c

28 Here, we report ballistic plasmonic Au nanoparticle (NP) swimmers with unprecedent

29 ssay on a U-bent fiber optic probe with gold plasmonic (AuNP) labels functionalized with anti-Mtb LAM

30 Plasmonic biosensing has emerged as the most sensitive l

31 t this problem by introducing a lateral flow plasmonic biosensor (LFPB) based on gold-viral biominera

32 We present a plasmonic biosensor capable of detecting the presence of

33 We report an antibiotic-mediated plasmonic biosensor for LPS detection based on a facile

34 Label-free plasmonic biosensors have demonstrated promising capabil

35 The integration of plasmonic biosensors with established and upcoming techn

36 a monolithic array of electrically-connected plasmonic bow-tie nanoantennas that are contained within

37 A plasmonic C-shaped engraving on a gold film is considere

38 diate dielectric cladding; implementation of plasmonic cavities and waveguides using plasmonic crysta

39 rough controllable chiral Purcell effects in plasmonic chiral metamaterials.

40 Herein, the recent progress in the field of plasmonic chirality is summarized, with a focus on both

41 variety of interesting properties, including plasmonic chiroptical activity in the visible spectrum,

42 ano-resolution optical imaging, sensors, and plasmonic circuits.

43 resent a light-gated protocell model made of plasmonic colloidal capsules (CCs) assembled with bacter

44 terization of high quality and biocompatible plasmonic colloidal nanoparticles has fostered numerous

45 The fast and reversible switching of plasmonic color holds great promise for many application

46 ein, we report a novel strategy to fabricate plasmonic color-switchable silver nanoparticle (AgNP) fi

47 ed to solution phases, achieving solid-state plasmonic color-switching has remained a significant cha

48 hanced light-matter interaction and low-loss plasmonic configurations by coupling to the spin-polariz

49 The plasmonic construct consists of a bovine serum albumin s

50 The plasmonic core of the spasers serves also as a photother

51 A detailed calculation of the plasmonic coupling between equivalent particles suggests

52 In the present work, we found that the plasmonic coupling of nearby Ag nanocubes does not only

53 olling the nanoparticle separation and their plasmonic coupling.

54 highlighting the imaging potential of these plasmonic "crystal balls." Emitters at the center are no

55 n of plasmonic cavities and waveguides using plasmonic crystals; and development of deep-subwavelengt

56 (AFB(1)) as an example based on the PTEs of plasmonic Cu(2- x)Se nanocrystals (NCs).

57 By loading plasmonic Cu(2- x)Se NCs into liposomes to form photothe

58 c bandgap and strong modulation of the local plasmonic density of states that can be turned on/off or

59 e analysis, overcomes current limitations of plasmonic detection systems.

60 ese results indicate that the performance of plasmonic devices can be greatly improved beyond that of

61 n loading, and hydrogen-switched mirrors and plasmonic devices have been realized, but challenges rem

62 he essential field-confinement capability of plasmonic devices is always accompanied by a parasitic O

63 trengths need to be well beyond what current plasmonic devices provide.

64 These sodium-based plasmonic devices show stable performance under ambient

65 Here we present stable sodium-based plasmonic devices with state-of-the-art performance at n

66 In the design of novel plasmonic devices, a central topic is to clarify the int

67 y saving and energy generation applications, plasmonic devices, Surface-Enhanced Raman Scattering (SE

68 provement over conventional high-performance plasmonic devices.

69 rovides another dimension for ultralow-index plasmonic devices.

70 solidified DNA frameworks to create 3D metal plasmonic devices.

71 ot-carrier distributions in nanophotonic and plasmonic devices.

72 In this study, a plasmonic droplet screen approach is developed for one-s

73 Herein, the plasmonic effect is introduced to improve the photoanode

74 universality has originated from the exotic plasmonic effect of Au colloids (i.e., localized surface

75 Here, the reported plasmonic effects are outlined, such as resonant energy

76 ttering) enhances the Raman signals, but the plasmonic effects are sensitive to the chemical environm

77 ccess to the control of optical (cooperative plasmonic effects), electronic (insulator to a conductor

78 This is accomplished by high plasmonic electric fields at the surface of plasmonic na

79 be a strategy based on the construction of a plasmonic electrode coupled with photoelectrochemistry,

80 s high as 30% as obtained with the batchwise plasmonic ELISA counterpart.

81 However, batchwise plasmonic ELISA involving end-point detection lacks rugg

82 r determination of emerging contaminants via plasmonic ELISA.

83 Plasmonics enables the manipulation of light beyond the

84 interfacial mechanism for the catalytic and plasmonic enhancement at interfaces that moves beyond th

85 olecule position-derived large variations in plasmonic enhancement can propel widespread application

86 teps is the first step in the translation of plasmonic enhancement sensing to a practical regime.

87 f lateral flow immunoassays (LFIA) utilizing plasmonic enhancement.

88 ) conditions to elucidate the nature of this plasmonic enhancement.

89 Plasmonic enzyme-linked immunosorbent assays (ELISA) usi

90 Our finding allows the treatment of plasmonic excitation as a reagent in chemical reactions;

91 In this approach, plasmonic excitation of Au nanoparticles produces a char

92 Here we show that plasmonic excitation of microscopic arrays composed of 5

93 pling magnetic and plasmonic anisotropy, the plasmonic excitation of the hybrid nanorods could be col

94 This study highlights the superiority of plasmonic excitation on improving electrocatalytic effic

95 ng from the zinc oxide excitation and copper plasmonic excitation serve to activate surface adsorbate

96 ve zinc oxide band-gap excitation and copper plasmonic excitation that can cooperatively promote meth

97 tropy allows control of the rod orientation, plasmonic excitation, and photothermal conversion by sim

98 sm through which the energy absorbed through plasmonic excitation, ultimately drives such reactions.

99 e is a chemical potential contributed by the plasmonic excitation.

100 lusters, which has important implications in plasmonic facilitated photocatalysis.

101 d periodic metal-dielectric layers to excite plasmonic Fano resonance transitions providing multimoda

102 Here, we report a plasmonic fiber optic absorbance biosensor (P-FAB) strat

103 of surface-mediated nonlinear excitation for plasmonic field enhancements highly concentrated at the

104 Classical plasmonic field simulations combined with quantum photoe

105 of light, and exist on the timescale of the plasmonic field.

106 The ability to visualize plasmonic fields evolving at the local speed of light on

107 displacement of NPs in dynamic assemblies by plasmonic fields followed by particle-to-particle attach

108 These plasmonic fields undergo spin-orbit interaction and thei

109 Such plasmonic films can be printed as high-resolution invisi

110 limitation prevents efficient application of plasmonic fluorescence enhancement for diversely-sized m

111 By using cell-culture experiments and plasmonic-force calculations, we demonstrate that the na

112 h provides independent control over both the plasmonic gap and photonic lattice modes of the surface-

113 k, a multiplexed grating-coupled fluorescent plasmonics (GC-FP) biosensor platform was used to rapidl

114 Herein, we developed a plasmonic gold nano-island (pGold) chip assay for diagno

115 f intracellular biomineralization to produce plasmonic gold nanoparticles at micromolar concentration

116 en demonstrated to have the capacity to form plasmonic gold nanoparticles when chloroauric acid is in

117 terization of multiphoton photoemission from plasmonic gold nanostars and demonstrate all-optical con

118 fluorescence amplification by nanostructured plasmonic gold substrates, for the simultaneous detectio

119 Plasmonics has recently emerged as an effective approach

120 verse transcription, fast thermocycling (via plasmonic heating through magneto-plasmonic nanoparticle

121 d assess the impact and utility of localized plasmonic heating.

122 t the spatial location of molecules within a plasmonic hot spot.

123 d in this work will enable quantification of plasmonic hot-carrier distributions in nanophotonic and

124 robe tip, that can provide quantification of plasmonic hot-carrier distributions.

125 A plasmonic "hotspot" confines and enhances optical excita

126 Magnetic-plasmonic hybrid Fe(3) O(4) /Ag nanorods are synthesized

127 Magnetic-plasmonic hybrid nanorods have been synthesized through

128 Using a plasmonic imaging approach, the oscillation amplitude is

129 However, classical plasmonic imaging systems have relatively poor spatial r

130 ulators for next generation compact photonic/plasmonic integrated circuits.

131 an be utilized as a unique means to modulate plasmonic interactions.

132 Plasmonics is a rapidly growing field spanning research

133 Plasmonic Laser Nanosurgery (PLN) is a novel photomodifi

134 icity of the plastic template decorated with plasmonic layers and surrounding dielectric medium.

135 results validate Ni as a promising low-cost plasmonic material for prompting visible-light photochem

136 Therefore, plasmonic materials (those with collective oscillations

137 Nanostructured plasmonic materials can lead to the extremely compact pi

138 work demonstrated a designed approach using plasmonic materials for enhanced diagnosis and monitorin

139 The combination of molecular sensors and plasmonic materials is emerging as one of the most promi

140 nanostructured probes that combine distinct plasmonic materials sandwiching a dielectric layer in a

141 large amount of loss that usually occurs in plasmonic materials(3).

142 , diffusive, angle-independent, and flexible plasmonic materials.

143 his work, we report on a series of ultrafast plasmonic measurements that provide a direct measure of

144 nt waves, such as electromagnetic, acoustic, plasmonic, mechanical, or quantum.

145 photonic rather than thermal, but the exact plasmonic mechanism is unknown.

146 Unlike conventional plasmonic media, polaritonic van der Waals (vdW) materia

147 um albumin are proposed as an ultrasensitive plasmonic mercury receptor on U-bend optical fiber platf

148 and analytic theory confirm the presence of plasmonic meron quasiparticles.

149 Light-driven synthesis of plasmonic metal nanostructures has garnered broad scient

150 By integrating plasmonic metamaterial absorbers with pyroelectric detec

151 undamental tools for the effective design of plasmonic metamaterials with on-demand functionality.

152 ls, optical-vortex generation and in tunable plasmonic metamaterials.

153 netic waves, which now play crucial roles in plasmonics, metamaterials, and nano-photonics.

154 he beam propagation is demonstrated by using plasmonic metasurfaces with the initial geometric phase

155 oped an ultrasensitive nanoparticle-enhanced plasmonic method for detecting ~1 aM RAS single nucleoti

156 poles associated with enantiomers and chiral plasmonic modes of CNAFs.

157 rove performance, even with the use of lossy plasmonic modes, are reviewed.

158 trong multidimensional coupling of localized plasmonic modes, resulting in a singular resonance with

159 A plasmonic modulator is a device that controls the amplit

160 umps, realizing a 2D semiconductor nonlinear plasmonic modulator, with an ultrafast response time of

161 al sensing structure configurations, such as plasmonic, multilayer, 2D, or metamaterial applications.

162 ere we show ultra-near-field index modulated PlAsmonic NanO-apeRture lAbel-free iMAging (PANORAMA) wh

163 f grapheneous sensor platforms for sensitive plasmonic nano-sensors.

164 Herein, a 3D plasmonic nanoantenna assay sensor is developed as an on

165 Additionally, our plasmonic nanoantenna-based biosensors are regenerative,

166 Based on the RIU results, we developed plasmonic nanoantenna-based multiplexing and high-throug

167 a bottom-up fabrication strategy to develop plasmonic nanoantenna-based sensors that utilize the uni

168 near-field nano-optical tweezers comprising plasmonic nanoantennas and photonic crystal cavities hav

169 Plasmonic nanocathodes offer unique opportunities for op

170 obing that exploits a gold nanoparticle in a plasmonic nanocavity geometry used as one terminal of a

171 vides insights into the Raman process at the plasmonic nanocavity, which may be useful in the nanosca

172 l, we realise disordered systems composed of plasmonic nanoclusters that either operate as a broadban

173 hereby making it possible to design magnetic/plasmonic nanocomposites that allow the dynamic tuning o

174 Branched plasmonic nanocrystals (NCs) have attracted much attenti

175 of a stochastically ordered distribution of plasmonic nanocrystals in a fractal scaffold of high-ind

176 function of providing structural support for plasmonic nanocrystals, which serve as nanoheaters, and

177 Here, we show that ultrathin plasmonic nanogaps support complete mode sets which stro

178 To realize such a material, we are combining plasmonic nanoheaters with alumina aerogel.

179 in concentration as low as 200 pg/mL for the plasmonic nanohole array and 1 ng/mL for the photonic cr

180 drodynamic tweezers employ a finite array of plasmonic nanoholes illuminated with light and an applie

181 ics, by creating SiO(2) nanospheres fused to plasmonic nanojunctions.

182 demonstrate a room-temperature sodium-based plasmonic nanolaser with a lasing threshold of 140 kilow

183 e, lower than values previously reported for plasmonic nanolasers at near-infrared wavelengths.

184 NA, and discuss the opportunity of utilizing plasmonic nanomaterials and tools for biomarker detectio

185 Stability strategies for other types of plasmonic nanomaterials, lithographic plasmonic nanopart

186 ver the past two decades, the development of plasmonic nanoparticle (NPs), especially gold (Au) NPs,

187 pes of plasmonic nanomaterials, lithographic plasmonic nanoparticle arrays, are discussed as well.

188 isulfide reaction kinetics and pathways on a plasmonic nanoparticle surface.

189 omatic molecules, the cyclic ring cluster of plasmonic nanoparticles (NPs) has been suggested as a pr

190 Plasmonic nanoparticles can strongly interact with adjac

191 The photoexcitation of plasmonic nanoparticles has been shown to drive multiste

192 Here, we use plasmonic nanoparticles to convert light into localized

193 he localized plasmon resonance (LSPR) of the plasmonic nanoparticles will change as a result of core-

194 Additionally, combining plasmonic nanoparticles with photo-activated substrates

195 cling (via plasmonic heating through magneto-plasmonic nanoparticles) and in situ fluorescence detect

196 structures, chiral assemblies of interacting plasmonic nanoparticles, and chiral metal metasurfaces a

197 ng photo-chemical reduction of gold salts to plasmonic nanoparticles, prescription of photoresponsive

198 anding of light-driven chemical reactions on plasmonic nanoparticles.

199 and how the molecular-like Au NCs transit to plasmonic nanoparticles.

200 plasmonic electric fields at the surface of plasmonic nanoparticles.

201 etals, with implications for applications in plasmonics, nanophotonics and metamaterials.

202 A literature review of recent plasmonic nanopore devices is then presented to delineat

203 Here, we show that a plasmonic nanoscale construct serving as an 'add-on' lab

204 n fabrication of spatially-coherent columnar plasmonic nanostructure superlattice-type thin films wit

205 e controlled anisotropic growth of colloidal plasmonic nanostructures and their dynamic modulation of

206 Plasmonic nanostructures can focus light far below the d

207 irect SERS strategy combined with the active plasmonic nanostructures has the potential for wide appl

208 er diode is used to simultaneously irradiate plasmonic nanostructures in a (scanning) transmission el

209 A series of positively charged plasmonic nanostructures including gold/silver nanospher

210 Enhancement of optical emission on plasmonic nanostructures is intrinsically limited by the

211 array is coated with an ensemble of metallic plasmonic nanostructures that only transmits light incid

212 utomatic vertical alignment of the resulting plasmonic nanostructures to the surface of the colloidal

213 fraction in photonic crystals, absorption of plasmonic nanostructures, as well as color-switching sys

214 uding molecular-plasmonic assemblies, chiral plasmonic nanostructures, chiral assemblies of interacti

215 Hot carriers in plasmonic nanostructures, generated via plasmon decay, p

216 pen up new possibilities for creating chiral plasmonic nanostructures, luminescent biological labels,

217 straightforward approach by combining active plasmonic nanostructures, surface-enhanced Raman spectro

218 es in regulating the morphology evolution of plasmonic nanostructures.

219 lm and AuNPs, as well as coupling effects in plasmonic nanostructures.

220 for the synthesis of symmetrically branched plasmonic NCs.

221 atial resolution, which is attributed to the plasmonic near-field confinement.

222 photonic media with thickness exceeding the plasmonic near-field enhancement region by more than two

223 x) NPLs provide an attractive alternative to plasmonic noble metal nanostructures for various plasmon

224 3 x 10(22) cm(-3), which is close to that of plasmonic noble metals, and thus our oxide-based nanostr

225 Plasmonics now delivers sensors capable of detecting sin

226 However, it remains challenging to assemble plasmonic NPs into complex networks exhibiting strong vi

227 nanostructures has been more challenging for plasmonic NPs than for the semiconductor due to the shor

228 Plasmonics on metal-dielectric interfaces was widely see

229 a subwavelength thick (<200 nm) Optofluidic PlasmonIC (OPtIC) microlens that effortlessly achieves o

230 ractal media are used for the fabrication of plasmonic optical gas sensors, achieving a limit of dete

231 structures incorporating both refractive and plasmonic optics, by creating SiO(2) nanospheres fused t

232 Plasmonic papers are characterized with respect to SERS

233 Common methods for synthesizing plasmonic particles are presented with the overall goal

234 ss it has opened by the ultrafast imaging of plasmonic phenomena on the nanofemto scale.

235 e and time coherent imaging of the dynamical plasmonic phenomena on the nanofemto scale.

236 only provides an ideal platform for studying plasmonic photochemistry in aqueous medium but also open

237 ations in electronics, sensing, spintronics, plasmonics, photodetectors, ultrafast lasers, batteries,

238 o-dimensional (2D) counterparts in fields of plasmonics, photonic crystals, and metamaterials.

239 nd in H(2) O is a critical, limiting step in plasmonic photosynthesis.

240 ) C/(13) C kinetic isotope effects (KIEs) in plasmonic photosynthesis.

241 hen coupled to a plastic optical fibre (POF) plasmonic platform, the analyte-induced nanoMIP-deformat

242 Additionally, on-chip guided plasmonic probe beams sample the terahertz signal effici

243 al and chemical parameters of AuNPs on their plasmonic properties as well as the use of these unique

244 tifunctional nanoparticles with magnetic and plasmonic properties assembled on a single nanoplatform

245 and how the stabilizing agents improve their plasmonic properties at the same time.

246 The plasmonic properties of metal nanoparticles can change s

247 The plasmonic properties of silver nanoparticle (AgNP) array

248 magnetic and near-infrared (NIR)-responsive plasmonic properties of the engineered nanostars enabled

249 rby Ag nanocubes does not only depend on the plasmonic properties of the main band.

250 ll changes in molecular structure affect the plasmonic properties of these chiral AgNP/APA hybrids.

251 omena and opens new directions for growth of plasmonics research.

252 c surface, an effect that dominates over any plasmonic resonance of the particle itself.

253 uding transmittance, interference color, and plasmonic resonance.

254 and fine-tuning of the aspect ratio and the plasmonic resonance.

255 dispersion, yielding a stronger and sharper plasmonic resonance.

256 h reduces the quality factor and darkness of plasmonic resonances and thus the sensitivity.

257 the input light producing excitation of the plasmonic resonances in the bow-tie nanoantennas, the SH

258 es via the multidimensional hybridization of plasmonic resonances.

259 reate a variety of chiral nanomaterials with plasmonic resonances.

260 horing the signal amplification and generate plasmonic resonant coupling between NPs and chip surface

261 nd allows for a more precise analysis of the plasmonic response.

262 eneral coupling phenomenon introduced as the plasmonic ruler equation in 2007.

263 s rise to changes in the decay length of the plasmonic ruler equation.

264 It involves a plasmonic sandwich immunoassay on a U-bent fiber optic p

265 This plasmonic-semiconductor fractal media supports the propa

266 the way for the development of reproducible plasmonic sensing for real-world quantitative applicatio

267 ecent developments on the different types of plasmonic sensing platforms, the pervasive challenges, a

268 which has potential application in improved plasmonic sensing, spectroscopy, and plasmon-based optic

269 vel class of sensitivity-gain structures for plasmonic sensing.

270 columnar heterostructures as a highly porous plasmonic sensor with optical read out sensitivity to fe

271 Plasmonic sensors exhibit a broad range of analytical ca

272 l-free platforms, including electrochemical, plasmonic, SERS-based and spectroelectrochemical biosens

273 paramagnetic iron oxide core and star-shaped plasmonic shell with high-aspect-ratio gold branches.

274 that detects analyte based on the change in plasmonic signal from thousands of single nanoparticles

275 ate and image a quasiparticle of topological plasmonic spin texture in a structured silver film.

276 miconductor due to the short lifetime of the plasmonic states.

277 effects in micrometer-scale hybrid photonic-plasmonic structures enable light switching under CMOS v

278 In contrast to plasmonic structures, the all-dielectric magnetic metasu

279 ration technique can be generalized to other plasmonic substrates and offers several additional advan

280 Herein we report a new method with plasmonic substrates capable of cell localization and en

281 ansfers chirality to both chiral and achiral plasmonic substrates, and it is also responsible for the

282 nd dynamically monitor their distance to the plasmonic surface at millisecond timescale.

283 onfiguration in which analytes interact with plasmonic surfaces, diversifying the resulting SERS fing

284 etect molecules with no specific affinity to plasmonic surfaces.

285 h surface-grafted agents to localize them on plasmonic surfaces; (3) physically confining liquid anal

286 g of the physics of disorder, our disordered plasmonic system provides a novel platform for various p

287 hat uses the decay rate enhancement(18) of a plasmonic system to increase device stability, while mai

288 unique capabilities of the strongly coupled plasmonic system via integration with an actively addres

289 Simultaneously, the use of plasmonic systems with giant light-interaction cross-sec

290 ve the controlled manipulation of disordered plasmonic systems, realising the transition from broadba

291 In this work, it is demonstrated that a plasmonic thin film composed of Au nanoparticles embedde

292 on process can allow for fabricating complex plasmonic TiN nanostructures and be integrated into the

293 Here, we demonstrate highly plasmonic TiN thin films and nanostructures by a room-te

294 , the typical high-temperature deposition of plasmonic TiN using either sputtering or atomic layer de

295 nd their superposition generates an array of plasmonic vortices.

296 mbrane that forms an air-gap hybrid photonic-plasmonic waveguide.

297 stals; and development of deep-subwavelength plasmonic waveguides and cavities using geometric engine

298 limitation by imaging scattering of surface plasmonic waves by proteins.

299 ure with a designed geometric phase generate plasmonic waves with different orbital angular momenta.

300 The field of plasmonics, which studies the resonant interactions of e