ライフサイエンスコーパス: metal nanoparticle

1 ocalized surface plasmon resonance (LSPR) of metal nanoparticle.

2 are allowed within the near-field of a noble metal nanoparticle.

3 microring, Fabry-Perot cavity, and plasmonic metal nanoparticle.

4 ic properties and surface chemistry of small metal nanoparticles.

5 of reducing metal salts to the corresponding metal nanoparticles.

6 on mechanisms, fate, and toxicity of natural metal nanoparticles.

7 can be achieved by optimizing the density of metal nanoparticles.

8 catalysis on surfaces of strongly plasmonic metal nanoparticles.

9 he graphene and hBN membranes with catalytic metal nanoparticles.

10 le nanomagnets based on carbon-coated cobalt metal nanoparticles.

11 lized surface plasmon resonance of colloidal metal nanoparticles.

12 well as its ability to organize and disperse metal nanoparticles.

13 cubic phases have not been reported in noble metal nanoparticles.

14 n various routes of synthesis of these noble metal nanoparticles.

15 rs and linear chains of strongly interacting metal nanoparticles.

16 sulfide in water enhanced with non-precious-metal nanoparticles.

17 enhancement of photoresponsive processes by metal nanoparticles.

18 nanostructured oxides to stabilize embedded metal nanoparticles.

19 cific compounds from a complex mixture using metal nanoparticles.

20 anoparticles to the exclusion of other noble metal nanoparticles.

21 consists of a mixture of oxide materials and metal nanoparticles.

22 lective reactivity and catalytic activity of metal nanoparticles.

23 pposed positions in the molecular coating of metal nanoparticles.

24 equilibration when they are in contact with metal nanoparticles.

25 oparticles as compared to mixtures of single-metal nanoparticles.

26 probe the binding of a variety of ligands to metal nanoparticles.

27 tical ones, implying the selective growth of metal nanoparticles.

28 logy, for the particular case of anisotropic metal nanoparticles.

29 ty and plasmonic properties of DNA-assembled metal nanoparticles.

30 interest due to unique optical properties of metal nanoparticles.

31 n of fluorescent molecules coupled to single metal nanoparticles.

32 W.m(-1).K(-1)) owing to the existence of Al metal nanoparticles.

33 de supports on reactions electrocatalyzed by metal nanoparticles.

34 pered by large analyte losses, especially of metal nanoparticles.

35 size, shape, morphology, and composition of metal nanoparticles.

36 (Pt, Co, and Ni) or alloyed (PtCo and PtNi) metal nanoparticles.

37 ed on localized surface plasmon resonance in metal nanoparticles.

38 t metal oxide materials decorated with noble metal nanoparticles advance visible light photocatalytic

39 Small noble-metal nanoparticles (Ag or Au) are directly synthesized

40 been shown that photoexcitation of plasmonic metal nanoparticles (Ag, Au and Cu) can induce direct ph

41 Silica-coated metal nanoparticles allow these systems to be combined w

42 such as QD interactions with gold and other metal nanoparticles along with carbon allotropes are als

43 iable sensors based on ligand-functionalized metal nanoparticles also known as monolayer-protected na

44 The plasmonics nanoprobe comprises a metal nanoparticle and a stem-loop DNA molecule tagged w

45 ermally decomposed in the presence of molten metal nanoparticles and coordinating ligands.

46 uctures and organize other materials such as metal nanoparticles and could in principle be used to nu

47 derstanding of the optical response of noble-metal nanoparticles and in the probing, analysis and vis

48 chemistry in the photoluminescence of small metal nanoparticles and largely rule out other mechanism

49 an innovative strategy for preparing shaped metal nanoparticles and make significant progress in the

50 enation of propylene in reactors packed with metal nanoparticles and metal-organic framework catalyst

51 d to direct the positioning and alignment of metal nanoparticles and nanorods.

52 Key advances in the synthesis of noble metal nanoparticles and nanostructures have resulted in

53 taking advantage of the synergy between the metal nanoparticles and oxide support.

54 tuning the composition and interface of the metal nanoparticles and oxide supports.

55 an be improved by synergic properties of the metal nanoparticles and polymer network with biomolecule

56 ic effect of the charge transfer between the metal nanoparticles and semiconductive components.

57 and-mediated layer-by-layer assembly between metal nanoparticles and small organic molecules, the aut

58 Control over the optical response of metal nanoparticles and their associated plasmons is cur

59 The natural existence of metal nanoparticles and their oxides/sulfides in waters,

60 e structures consisting of a QD coupled to a metal nanoparticle, and assembled into an ordered nanoar

61 kes a great use of supported late-transition-metal nanoparticles, and bimetallic catalysts often show

62 N-doped carbon and carbon nitride supported metal nanoparticles, and concentrates on the catalytic e

63 e to increased electron density at the noble-metal nanoparticles, and demonstrate the universality of

64 ne flakes, biological particles, SERS-active metal nanoparticles, and high-refractive semiconductor n

65 r/quartz interface and that reflected by the metal nanoparticles, and the resulting interference effe

66 etites are often found with other transition metal nanoparticles, and they display rounded crystal mo

67 Prereduced metal nanoparticles are combined in known ratios, and th

68 Metal nanoparticles are commonly supported on metal oxid

69 Metal nanoparticles are currently being employed as cata

70 nd the preparation of dendrimer-encapsulated metal nanoparticles are described.

71 The remarkable optical properties of metal nanoparticles are governed by the excitation of lo

72 Metal nanoparticles are important in several emerging te

73 Non-noble metal nanoparticles are notoriously difficult to prepare

74 Bimetallic hollow, porous noble metal nanoparticles are of broad interest for biomedical

75 Shape-controlled metal nanoparticles are of interest because of their wid

76 Metal nanoparticles are of particular interest because t

77 icient ligand-free first-row late transition-metal nanoparticles are prepared and compared.

78 tering of electromagnetic radiation by noble metal nanoparticles are strongly enhanced.

79 Metal nanoparticles are used as catalysts in a variety o

80 heir advantageous material properties, noble metal nanoparticles are versatile tools in biosensing an

81 Oxide-supported precious metal nanoparticles are widely used industrial catalysts

82 er of a noble metal on relatively cheap core-metal nanoparticles, are fascinating and promising fuel

83 the sensitivity of optical sensors based on metal nanoparticle arrays and single nanoparticles.

84 n of localized surface plasmon resonances in metal nanoparticle arrays.

85 The method employs colloidal metal nanoparticles as protein carriers and optical tags

86 ions of isolated or weakly-interacting noble-metal nanoparticles, as encountered in experiments, whil

87 reactions take place at the surface of noble metal nanoparticles at room temperature and can be accur

88 a method for quantification of the number of metal nanoparticles at the single-cell level.

89 occur in light-mediated self-organization of metal nanoparticles; atoms are replaced by silver nanopa

90 ovide a general methodology in the design of metal-nanoparticle-based catalysts for a broad range of

91 Again, we have pointed out the impact of the metal-nanoparticle-based surface energy transfer process

92 ried out on a massively parallel scale using metal nanoparticle building blocks of specific shape.

93 y growing the secondary metal on the primary metal nanoparticle but not on the support; meanwhile, th

94 izing optical metamaterials based upon noble metal nanoparticles by enabling the crystallization of l

95 Free electrons in a noble metal nanoparticle can be resonantly excited, leading to

96 ht-excited metal electrons on the surface of metal nanoparticles can activate the adsorbed reactant m

97 The catalytic and optical properties of metal nanoparticles can be combined to create platforms

98 Since metal nanoparticles can be densely implanted as inclusio

99 The adsorption of molecules on metal nanoparticles can be sterically controlled through

100 apping, and the size of thermally evaporated metal nanoparticles can be tuned by either post heat tre

101 electron reactivity are chosen, immobilized metal nanoparticles can exhibit a highly enhanced chemic

102 Metal nanoparticles can generate gigantic field enhancem

103 Metal nanoparticles can induce cell death, yet the toxic

104 work, we discovered that light scattering of metal nanoparticles can provide 3D imaging contrast in i

105 ents of the circuitry can be interfaced with metal nanoparticles capable of sensing various environme

106 oxygen reduction reaction (ORR) kinetics of metal nanoparticle catalysts between 500 and 600 degrees

107 gy for preparing highly dispersed, ultrafine metal nanoparticle catalysts on an electroactive polymer

108 Unlike metal nanoparticle catalysts, zirconia-based growth shou

109 age consistently found with nanotube-bearing metal nanoparticle catalysts.

110 cle catalysts versus typical oxide-supported metal nanoparticle catalysts.

111 lectrode activity to the best known precious metal nanoparticle catalysts: platinum, ruthenium, and i

112 Atomic-scale insights into how supported metal nanoparticles catalyze chemical reactions are crit

113 ause of widespread use, but it is unclear if metal nanoparticles cause effects directly or indirectly

114 ar, prevented their use in the design of all-metal nanoparticle circuitry.

115 portant new synthetic route to control final metal nanoparticle composition and composition architect

116 Deformable, spherical aggregates of metal nanoparticles connected by long-chain dithiol liga

117 etallic (or plasmonic) to molecular state in metal nanoparticles constitutes a central question in na

118 ccur at the geometrically bounded surface of metal nanoparticles continues to advance as new and more

119 ectret (poly(2-vinyl naphthalene) (PVN)) and metal nanoparticles (Copper).

120 th Raman reporter-functionalized SERS-active metal nanoparticles (core/satellite silver nanoparticles

121 al/metal oxide nanoparticles, polymer-coated metal nanoparticles, dendrimers, micelles and star polym

122 ng this reaction are often composed of noble metal nanoparticles deposited on a semiconductor.

123 In general, we show that the metal nanoparticle deposition method is effective for ti

124 analogous to the electrochemical behavior of metal nanoparticles described by Plieth's model.

125 The incorporation of noble metal nanoparticles, displaying localized surface plasmo

126 ance across the gaps due to the formation of metal nanoparticle-DNA complexes is measured over time a

127 plasmon resonance (LSPR) occurring in noble metal nanoparticles (e.g., Au) is a widely used phenomen

128 new properties derived from the presence of metal nanoparticles (e.g., bacteriostaticity, increased

129 tion and for the electrodeposition of single metal nanoparticles (e.g., Pt, Pd) for studies as electr

130 ent of an expanded graphite embedded with Al metal nanoparticles (EG-MNPs-Al) synthesized by an oxida

131 fiber Bragg grating (TFBG) coated with noble metal nanoparticles, either gold nanocages (AuNC) or gol

132 the size, shape and composition of catalytic metal nanoparticles, enabling their use as model catalys

133 Plasmonic metal nanoparticles enhance chemical reactions on their

134 hesis, stability, and toxicity of engineered metal nanoparticles (ENPs) have been extensively studied

135 vacancies and dopants such as Ni that afford metal nanoparticle exsolution.

136 periments and in electrodeposition of single metal nanoparticles for electrocatalytic studies because

137 Supported metal nanoparticles form the basis of heterogeneous cata

138 four-step mechanism of supported transition-metal nanoparticle formation in contact with solution: s

139 d first worked out for monitoring transition-metal nanoparticle formation in solution.

140 Recent work with this prototype transition-metal nanoparticle formation system revealed that nuclea

141 racterization of large numbers of individual metal nanoparticles freely diffusing in colloidal soluti

142 rticle, the physical distance separating the metal nanoparticle from the organic dye, and the spectra

143 tronic circuits can be made exclusively from metal nanoparticles functionalized with charged organic

144 Although metal nanoparticle/graphene composites have been widely

145 polyelectrolyte coatings, magnetic and noble metal nanoparticles, hard mineral shells and other compl

146 (VSCR) between small-molecule reactants and metal nanoparticles has been demonstrated in several stu

147 nsights on high surface area oxide supported metal nanoparticles has been limited by less than atomic

148 The use of plasmon coupling in metal nanoparticles has shown great potential for the op

149 ce plasmons in one-dimensional assemblies of metal nanoparticles have attracted significant attention

150 Shape- and size-controlled syntheses of metal nanoparticles have been achieved by galvanic displ

151 Aggregated metal nanoparticles have been known to display significa

152 The unique optical properties of noble metal nanoparticles have been used to design a label-fre

153 configurations of surface atoms on supported metal nanoparticles have different catalytic reactivity

154 Noble-metal nanoparticles have had a substantial impact across

155 and the optical and catalytic properties of metal nanoparticles have led to similar advances in plas

156 A pressing problem in supported-metal-nanoparticle heterogeneous catalysis--despite the

157 bits the excellent characteristics of carbon-metal nanoparticle hybrid conjugation and led to the amp

158 cision required at the nanoscale to position metal nanoparticles in 3D.

159 integrating an easily deformable network of metal nanoparticles in a hydrogel matrix for use as a ca

160 and optically mediated assembly of plasmonic metal nanoparticles in DNA-hybridization assays.

161 monitoring of complex environments and noble metal nanoparticles in real time.

162 This is the first report of colloidal metal nanoparticles in the form of single plasmonic subs

163 ally catalyze new biomedical applications of metal nanoparticles in the fundamental understanding of

164 silver ions and subsequently nucleate silver metal nanoparticles in water.

165 re substantially better than those for other metal nanoparticles, including gold, owing to an effecti

166 accurately describe the optical response of metal nanoparticles, including retardation effects, with

167 Transition metal nanoparticles, including those employed in catalyt

168 aintains the Raman label in proximity to the metal nanoparticle, inducing an intense surface-enhanced

169 Metal nanoparticle infiltration resulted in significantl

170 cation of dynamic 1:1 inclusion complexes of metal nanoparticles inside oxide nanocups with high yiel

171 lity, selectivity, and activity of catalytic metal nanoparticle interfaces represents a challenge to

172 produce composite materials that consist of metal nanoparticles interspersed with the poly-Pd(n)C60

173 followed by electron transfer (ET) from the metal nanoparticle into TiO2.

174 The incorporation of metal nanoparticles into a polymer matrix can effectivel

175 Incorporation of metal nanoparticles into active layers of organic solar

176 ical hierarchical structure with embedded Al metal nanoparticles into the interspaces of expanded gra

177 a combination of polymeric monolayers and a metal nanoparticle intralayer.

178 ombining different semiconducting oxides and metal nanoparticles is as well explored.

179 Engineering the surface ligands of metal nanoparticles is critical in designing unique arra

180 The sensing efficiency or factor of noble metal nanoparticles is defined as the wavelength shift o

181 Much of the interest in noble metal nanoparticles is due to their plasmonic resonance

182 rol over charge transfer in carbon-supported metal nanoparticles is essential for designing new catal

183 The electrochemical behavior of small metal nanoparticles is governed by Coulomb-like charging

184 The peak position of the LSPR for noble-metal nanoparticles is highly dependent upon the refract

185 ed surface plasmon resonance (LSPR) of noble metal nanoparticles is highly dependent upon the refract

186 scopic understanding of thermal behaviors of metal nanoparticles is important for nanoscale catalysis

187 echanisms of catalytically active transition metal nanoparticles is important to improve their applic

188 The size of metal nanoparticles is one of key factors to strong ligh

189 single-layer graphene sensor decorated with metal nanoparticles is presented.

190 near-field coupling between individual noble metal nanoparticle labels to resolve subdiffraction limi

191 similar vein, polyoxometalates can stabilize metal nanoparticles, leading to additional transformatio

192 lts occurs spontaneously in the gel to yield metal nanoparticles located on the gel nanofibers.

193 hemical current densities in metal-insulator-metal nanoparticle (M-I-MNP) systems.

194 on leads to a larger dispersion of supported metal nanoparticles (M = Au, Cu, Pt) and makes possible

195 he presence of potentially interfering other metal nanoparticles (M-NPs) and dissolved organic matter

196 Nanomaterials such as metal nanoparticles, metal nanoclusters, metal oxide nan

197 ly friendly chemistry approach to synthesize metal-nanoparticle (MNP)-embedded paint, in a single ste

198 rameworks (MOFs) as porous matrices to embed metal nanoparticles (MNPs) and occasionally metal oxide

199 Weakly protected metal nanoparticles (MNPs) are used as precursors for th

200 A range (Au, Pt, Pd) of metal nanoparticles (MNPs) has been prepared and functio

201 The release of metal nanoparticles (MNPs) to the environment could be d

202 Composites incorporating metal nanoparticles (MNPs) within metal-organic framewor

203 found that a range of nanomaterials such as metal nanoparticles (MNPs), carbon based nanomaterials,

204 varying the experimental conditions: type of metal nanoparticles, molecular linker (aromatic versus a

205 Monolayer-protected metal nanoparticles (MPMNs) are a newly discovered class

206 Recent advances include memories based on metal nanoparticles, nanoscale phase-change materials an

207 of the rose petals allows us to concentrate metal nanoparticle (NP) aggregates and analytes onto the

208 Metal nanoparticle (NP) films, prepared by adsorption of

209 ssion levels, we demonstrate here that noble metal nanoparticle (NP) immunolabeling in combination wi

210 trode based on an insulating TiO2 film and a metal nanoparticle (NP).

211 To date the self-assembly of ordered metal nanoparticle (NP)/block copolymer hybrid materials

212 Transition metal nanoparticles (NPs) are typically supported on oxi

213 e present a novel approach by which adsorbed metal nanoparticles (NPs) are used for enhancing ET exch

214 Experiments at individual metal nanoparticles (NPs) can provide important informat

215 Electrochemistry at individual metal nanoparticles (NPs) can provide new insights into

216 alumina (Al(2)O(3)) overcoating of supported metal nanoparticles (NPs) effectively reduced deactivati

217 Chemical environment control of the metal nanoparticles (NPs) embedded in nanocrystalline me

218 The noble metal nanoparticles (NPs) exhibit high electrocatalytic

219 Nanostructures decorated with noble metal nanoparticles (NPs) exhibit potential for use in h

220 Many chemical and biosensors based on metal nanoparticles (NPs) have been developed.

221 ugation of organic dyes onto non-luminescent metal nanoparticles (NPs) have greatly broadened their a

222 pane derivatives under hydrogen catalyzed by metal nanoparticles (NPs) in the liquid phase were studi

223 bilization events of single electrocatalytic metal nanoparticles (NPs) on an inert electrode.

224 Shape-controlled synthesis of metal nanoparticles (NPs) requires mechanistic understan

225 lectrospray plume on a surface yielded noble metal nanoparticles (NPs) under ambient conditions.

226 Investigating the collisions of individual metal nanoparticles (NPs) with electrodes can provide ne

227 Metal nanoparticles (NPs) with size comparable to their

228 PS beads and poly(vinyl pyrrolidone)-capped metal nanoparticles (NPs), homogeneous and dense metal c

229 opolymer micelles and polymer-tethered noble-metal nanoparticles (NPs).

230 factant-assisted synthesized colloidal noble metal nanoparticles (NPs, such as Au NPs) on solids is a

231 ing the innerwall and outerwall of CNTs with metal nanoparticles of different shapes was also achieve

232 Self-assembly of charged, equally sized metal nanoparticles of two types (gold and silver) leads

233 spatiotemporal catalytic behaviors of single metal nanoparticles of various shapes including pseudosp

234 ause the surface plasmon resonances of noble metal nanoparticles offer a superior optical signal and

235 Branched metal nanoparticles often display unique physicochemical

236 d with localized surface plasmons excited in metal nanoparticles on a quartz substrate is observed an

237 owth of a finely dispersed array of anchored metal nanoparticles on an oxide electrode through electr

238 Potential effects of metal nanoparticles on aquatic organisms and food webs a

239 ort a new method to deposit metal oxides and metal nanoparticles on graphene and form stable metal-me

240 The as-prepared noble metal nanoparticles on MXene show a highly sensitive SER

241 Rhodium oxide and rhodium metal nanoparticles on niobate and tantalate supports ar

242 ce-enhanced Raman spectroscopy studies using metal nanoparticles on Si/SiO2 substrates.

243 with NaBH4 and the in situ deposition of the metal nanoparticles on the 2D carbon nanomaterial planar

244 ves deposition of a submonolayer coverage of metal nanoparticles on the surface of a polymer sample e

245 exploited to site-selectively deposit these metal nanoparticles onto the outerwall, innerwall, or en

246 we demonstrate high-fidelity fabrication of metal nanoparticles, optical nanoantennas, and nanohole

247 generated from either localized plasmons in metal nanoparticles or propagating plasmons in patterned

248 n of the induced electron oscillation in the metal nanoparticle oriented by the electromagnetic field

249 This method can be extended to metal nanoparticles other than Au and Ag and with a rang

250 Success has recently been achieved for metal nanoparticles, particularly Au, with diameters up

251 These noble metal nanoparticles, particularly of gold, have elicited

252 r CeO(2)), which in turn contained dispersed metal nanoparticles (Pd or Pt).

253 thods for brief discussion of fabrication of metal nanoparticles-polymer hybrid materials and their a

254 Metal nanoparticles prepared by exsolution at the surfac

255 Currently, polymer thin films embedded with metal nanoparticles provided the suitable microenvironme

256 The metal nanoparticles self-assemble into nanonetworks, for

257 , such as semiconducting quantum dots (QDs), metal nanoparticles, semiconductor-metal heterostructure

258 tions), creating electronic devices in which metal nanoparticles sense, process and ultimately report

259 of the next generation of these immobilized metal nanoparticle sensors.

260 These mixed-metal nanoparticles show excellent catalytic properties

261 rystals with the catalytic activity of small metal nanoparticles show promising applications for phot

262 The spectroscopy of metal nanoparticles shows great potential for label-free

263 -coated surfaces (metal mirrors) enhanced by metal nanoparticles (silver island films [SIFs]).

264 ing synthetic protocols that reduce precious metal nanoparticle size and stabilize dispersed species

265 ental results are illustrated in the case of metal nanoparticles, stressing the key role played by th

266 Noble metal nanoparticles such as gold, silver and platinum ar

267 Noble metal nanoparticles supporting plasmonic resonances beha

268 , as well as demonstrate the pivotal role of metal nanoparticle surface chemistry in tuning and optim

269 yer adsorbate molecules on differently sized metal nanoparticle surfaces investigated with ultrafast

270 cement of fluorophores in close proximity to metal nanoparticle surfaces is proposed to enhance sever

271 on unanswered mechanistic questions in noble-metal nanoparticle synthesis and promising directions fo

272 overtakes performances of previous non-noble metal nanoparticles systems, and is even better than som

273 systems, and is even better than some noble metal nanoparticles systems.

274 tructed from precise numbers of well-defined metal nanoparticles that are held together with molecula

275 Liquid metal nanoparticles that are mechanically sintered at an

276 Metal nanoparticles that comprise a few hundred to sever

277 MPCs are metal nanoparticles that have unique optical, chemical,

278 Brust-Schiffrin syntheses of the respective metal nanoparticles, through which the different reactio

279 Raman label to physically separate from the metal nanoparticle, thus quenching the SERS signal.

280 Both SLS and VLS methods make use of molten metal nanoparticles to catalyse the nucleation and elong

281 ize localized surface plasmon resonance from metal nanoparticles to enhance electromagnetic fields in

282 the details of the transformation from solid metal nanoparticles to hollow metal oxide nanoshells via

283 seed refinement leads to unprecedented noble metal nanoparticle uniformities and purities for eight d

284 here is a longstanding challenge to disperse metal nanoparticles uniformly in bulk polymers for wides

285 Identifying the ripening modes of supported metal nanoparticles used in heterogeneous catalysis can

286 ractionation (ElFFF) for characterization of metal nanoparticles was investigated in this study.

287 ons and the stabilization effect of PAMAM on metal nanoparticles were investigated by FT-IR.

288 These CNT-supported metal nanoparticles were shown to possess interesting op

289 However, this model may not be pertinent for metal nanoparticles, which are now understood to be ubiq

290 is afforded by plasmon-mediated syntheses of metal nanoparticles, which use visible light irradiation

291 It has long been a challenge to dope metal nanoparticles with a specific number of heterometa

292 networks from single and binary mixtures of metal nanoparticles with a triblock terpolymer.

293 port a new strategy to synthesize core-shell metal nanoparticles with an interior, Raman tag-encoded

294 molecularly mediated thin film assemblies of metal nanoparticles with controllable interparticle spat

295 ion from molecular to plasmonic behaviour in metal nanoparticles with increasing size remains a centr

296 Metal nanoparticles with precisely controlled size and c

297 , our studies show high affinity between the metal nanoparticles with the graphene.

298 er in the development of new preparations of metal nanoparticles with well-defined shapes.

299 ron microscope images of monolayer-protected metal nanoparticles, with ligand shells composed of a mi

300 llized via targeted deposition and growth of metal nanoparticles, yielding high-conductivity bioelect