ライフサイエンスコーパス: nanorod

1 etics are maintained within the neighbouring nanorod.

2 the conduction band of the CdS semiconductor nanorod.

3 oustic signals, compared to a plasmonic gold nanorod.

4 provide the aspect ratio and the size of the nanorods.

5 atalytic activities on single titanium oxide nanorods.

6 d magnetic nano-clusters and radiopaque gold nanorods.

7 Au core-shell particles, Au nanocages and Au nanorods.

8 d samples, showed arrangement of fibers into nanorods.

9 vesting process in highly adaptable metallic nanorods.

10 ing and alignment of metal nanoparticles and nanorods.

11 ne over ceria nanocubes, nano-octahedra, and nanorods.

12 nanoparticles, i.e., gold nanocages and gold nanorods.

13 ose on the surface of free-standing catalyst nanorods.

14 r, kidneys and spleen for less time than the nanorods.

15 epitaxial growth on the tips of rutile TiO2 nanorods.

16 t separation and the smallest diameter of Ag nanorods.

17 centration at the junction between the fused nanorods.

18 for cells consisting of the smallest bandgap nanorods.

19 higher than identical composites containing nanorods.

20 ip were near unity for both CdS and CdSe/CdS nanorods.

21 ecules to immobilize onto the surface of the nanorods.

22 ng and cooling rates disappears for small MG nanorods.

23 compared to that from an ensemble of random nanorods.

24 rg-Gly-Asp (RGD) peptide-functionalized gold nanorods.

25 shells on PEG-disulfide functionalized gold nanorods.

26 Zinc oxide (ZnO) nanorods (214 +/- 45 nm in diameter and 1.08 +/- 0.11 mu

27 oth endogenous (melanin) and exogenous (gold nanorods) absorbers.

28 nal transition of CdSe using single nanowire/nanorod absorption spectroscopy.

29 Transport of nanorods across the intestinal co-culture was also signi

30 tive rapid detection of H2S gas using silver nanorods (AgNRs) arrays on glass substrates at ambient c

31 ctions designed into colloidal semiconductor nanorods allow both efficient photocurrent generation th

32 ymmetric modification with an enzyme confers nanorods an enhanced diffusive motion that is dependent

33 on transport is not confined within a single nanorod and may provide a paradigm shift for one-dimensi

34 nanoparticles) are synthesized with both the nanorod and the sea-urchin-arm dimensions controlled by

35 temperature expedites random curving of ZnO nanorods and forms nano-worms.

36 at the nanoscale, using metallic glass (MG) nanorods and in situ transmission electron microscopy.

37 visible microspheres that included both gold nanorods and magnetic clusters.

38 d for large-scale preparation of NaLa(MoO4)2 nanorods and microflowers co-doped with Eu(3+) and Tb(3+

39 hape transformation of Au@Ag core-shell NPs (nanorods and nanocubes) into octahedral nanorattles via

40 on block copolymer (BCP) blended with linear nanorods and nanoscale tetrapod Quantum Dots (tQDs), in

41 ous nanoantennas such as V-shape structures, nanorods and nanoslits.

42 onductor thin films and comparable with some nanorods and nanowires.

43 to efficiency of hot-electron harvesting in nanorods and reveal that increasing the aspect ratio can

44 nanoscale features of mechanically hard ZnO nanorods and the mechanical durability derives from the

45 smon mediated generation of hot electrons in nanorods and the rate of injecting them into other media

46 The oxidase-modified nanorods and their calibration curves were finally used

47 strong luminescence are prepared using gold nanorods and upconversion nanoparticles.

48 e observations that physical contact between nanorods and virus particles was not required for viral

49 y used morphologies: nanostars, nanospheres, nanorods, and nanoplates is designed.

50 Specifically, single crystal nanowires, nanorods, and nanoplates of methylammonium lead halide p

51 s of various shapes including pseudospheres, nanorods, and nanoplates.

52 raft a variety of plain nanorods, core-shell nanorods, and nanotubes with precisely controlled dimens

53 o selectively functionalize the ends of gold nanorods, and robust methods are developed to reliably d

54 Unexpected etching of nanocrystals, nanorods, and their heterostructures by one of the most

55 Zn oleate is shown to etch CdS nanorods anisotropically, where the length decreases wit

56 Smectic-like ordering of the nanorods appears very early in the process, as soon as n

57 The colloidal nanodisks and nanorods are coassembled into AB-, AB2-, and AB6-type bi

58 ectrochemical activity of single-crystal CoO nanorods are in the oxygen vacancies that can be readily

59 edox tag, the volume and surface area of the nanorods are measured, and provide the aspect ratio and

60 ng, we demonstrate that trapped holes in CdS nanorods are mobile and execute a random walk at room te

61 The hierarchical FeOF nanorods are promising high-capacity cathodes for SIBs.

62 s demonstrate that the as-synthesized hybrid nanorods are promising imaging probes with improved sens

63 , CdSe/CdSe(x)Te(1-x) type-II heterojunction nanorods are utilized as novel light harvesters for sens

64 sensors were assembled onto a patterned ZnO nanorod array deposited on the synthetic silicone hydrog

65 nsity femtosecond lasers with aligned copper nanorod array targets.

66 An electrode of a 3D nanorod array, having a larger surface-to-volume ratio t

67 ond optical nonlinearity of indium tin oxide nanorod arrays (ITO-NRAs) following intraband, on-plasmo

68 Here Ti nanorod arrays (TNrs) with different densities were prod

69 using GD powder as the vapor source and ZnO nanorod arrays as the substrate.

70 matic approach to tailor effective plasmonic nanorod arrays by combining both comprehensive numerical

71 Furthermore, we demonstrate the use of nanorod arrays for the detection of single nucleotide po

72 l reactions on electrochemically grown metal nanorod arrays in porous anodic aluminum oxide templates

73 izing GD films with 2D nanostructures on ZnO nanorod arrays through a combination of reduction and a

74 Our work shows significant potential of nanorod arrays towards point-of-care applications in dia

75 Well-ordered Au-nanorod arrays were fabricated using the focused ion bea

76 The results indicate that 200x50 nm nanorod arrays with 300x500 nm period provide the highes

77 -cell fusion using bulk metallic glass (BMG) nanorod arrays with varying biophysical cues, i.e. nanot

78 tipole plasmon modes for closely spaced gold nanorod arrays, offering a new insight into the higher o

79 ed hydrolysis and post calcination using ZnO nanorod as a template.

80 free colorimetric assay using palladium-gold nanorod as nanozyme is reported for malathion detection.

81 Here, using gold nanorods as model plasmonic systems, InAs quantum dots (

82 point pen filled with biofunctionalized gold nanorods as plasmonic ink for creating isolated test dom

83 e by using vertically aligned semiconducting nanorods as the 3D photosensing pixels.

84 tting diodes utilizing double-heterojunction nanorods as the electroluminescent layer are demonstrate

85 ally functionalize the ends or the side of a nanorod, as well as the gaps between two rods, with diff

86 By adjusting the nanorod aspect ratio (length to width ratio), desired ab

87 higher percentage of injected dose than the nanorods at both the 7 and 28 day time points.

88 We show that gold nanorods (Au NRs) can be synthesized with tunable plasmo

89 Three-layer core-shell plasmonic nanorods (Au/Ag/SiO2-NRs), consisting of a gold nanorod

90 m two dissimilar plasmonic materials: a gold nanorod (AuNR) core and a copper selenide (Cu(2-x)Se, x

91 articles, especially those growing from gold nanorod (AuNR) seeds, are underexplored; however, the Au

92 also facilitate loading the prodrug on gold nanorod (AuNR)-encapsulated graphitic nanocapsule (AuNR@

93 proach that utilizes DNA-functionalized gold nanorods (AuNRs) in an indirect competitive assay format

94 multifunctional nanocomposite system of gold nanorods (AuNRs) was developed.

95 phene) (P3HT) nanoribbons and plasmonic gold nanorods (AuNRs) were crafted by a co-assembly of thiol-

96 Gold nanorods (AuNRs) were first loaded into PLTs by electrop

97 Among plasmonic nanoparticles, gold nanorods (AuNRs) with specific dimensions enabling them

98 Gold nanorods (AuNRs)-assisted plasmonic photothermal therapy

99 istance between UCNPs and nanoantennae (gold nanorods, AuNRs) was precisely tuned by using layer-by-l

100 ld of the obtained NPs, which in the case of nanorods avoids the need for additives such as Ag(+) ion

101 articles (NPs), with preselected morphology (nanorods, bipyramids, and decahedra) and aspect ratio.

102 ic optical perturbation that are confined by nanorod boundaries, modelled as finite cylindrical poten

103 he tetragonal superlattice of octagonal gold nanorods, breaking through the only hexagonal symmetry o

104 the potential use of such emerging dual mode nanorod bundles as photon sources for next generation fl

105 ting/downshift Y1.94O3:Ho(3+)0.02/Yb(3+)0.04 nanorod bundles by a facile hydrothermal route has been

106 These luminescent nanorod bundles exhibit strong green emission at 549 nm

107 lop a hierarchically ordered array of silver nanorod bundles for surface-enhanced Raman scattering (S

108 A hierarchically ordered array of Ag-nanorod bundles is achieved using an inexpensive binary-

109 cence intensity distribution in upconverting nanorod bundles using confocal microscopy is reported.

110 photoluminescence microscope throughout the nanorod bundles.

111 ional single-crystal cobalt (II) oxide (CoO) nanorods by creating oxygen vacancies on pyramidal nanof

112 performance of chemical bath deposited TiO2 nanorods by decorating Pd nanoparticle catalyst.

113 dy we show that it is possible to image gold nanorods by detecting their anti-Stokes emission under r

114 plex patterns of high quality single crystal nanorods can be formed in-situ with significant advantag

115 of the outermost surface of cobalt(II) oxide nanorods can turn them into efficient electrocatalysts f

116 Transferrin-coated endocytic gold nanorod cargoes initially undergo active rotational diff

117 ssembled novel stair-like and coil-like gold nanorod chiral metastructures, which is strongly affecte

118 ch immobilizes the analyte and drives the Au-nanorod close to each other and close to the Ag-ZnO nano

119 idally orientational self-assemblies of gold nanorods co-dispersed with cellulose nanocrystals to for

120 rystals (such as gold nanoparticles and gold nanorods) coated with mixed hydrophilic and hydrophobic

121 A mixture of thermo-responsive microgels, Au-nanorods colloids and analyte solution is then filled in

122 s shaped like split rings, nanowire pairs or nanorods (commonly referred to as meta-atoms) that are a

123 s from the composite structure of a hard ZnO nanorod core and soft polymer shell.

124 orods (Au/Ag/SiO2-NRs), consisting of a gold nanorod core, a thin silver shell, and a thin silica lay

125 general strategy to craft a variety of plain nanorods, core-shell nanorods, and nanotubes with precis

126 the polarized emission of individual quantum nanorods coupled to the dynein ring, we determined the a

127 Furthermore, by using gold nanorods covered with phosphatidylglycerol layers and si

128 Dual-functional cupric oxide nanorods (CuONRs) as peroxidase mimics are proposed for

129 ing the chiral directional "bonding" of gold nanorods decorated by the surface adapter.

130 a colloid-type sensor using a few "bare" Au nanorods deposited on the surface of a colloidal chitosa

131 By controlling the MG nanorod diameter and crystallization kinetics, we can tu

132 d nanorod heights while the influence of the nanorod diameter is relatively insignificant.

133 crystallization kinetics is affected by the nanorod diameter.

134 We self-assemble plasmonic nanorod dimers with a longitudinal offset that determine

135 and dynamic control over an assembly of gold nanorods dispersed in liquid crystals (LC) is demonstrat

136 Gold nanorods, DNA origami, and porous silicon nanoparticle-f

137 ladder cancer using the NMP22 MIP-coated ZnO nanorods electrodes that were integrated into a portable

138 core-shell structure consisting of germanium nanorods embedded in multiwall carbon nanotubes.

139 orientational ordering of the semiconductor nanorods emerge from competing long-range elastic and el

140 In our experiments, InGaAsP nanorods emitting at approximately 200 THz optical frequ

141 und with electron microscopy analysis of the nanorods, establishing the application of nano-impact ex

142 improves the overall performance of a given nanorod--even though more improvement in photocurrent ef

143 nanospheres and nanopallets and report that nanorods exhibit significantly better performance over a

144 These CoO nanorods exhibit superior catalytic activity and durabil

145 The utility of luminomagnetic nanorods for biological applications in high-contrast ce

146 ificant advantages over competing methods of nanorod formation for plasmonics, energy storage and sen

147 Nanorod formation involves cobalt nucleation, a fast ato

148 ope to observe the transformation of an HfO2 nanorod from monoclinic to tetragonal, with a transforma

149 Particularly, we template nanorods from a mixture of superparamagnetic Zn0.2Fe2.8O

150 ling the diameter and separation of metallic nanorods from physical vapor deposition through self-org

151 paramagnetism of Zn0.2Fe2.8O4 prevents these nanorods from spontaneous magnetic-dipole-induced aggreg

152 As a result, Co-Fe-P nanorods (from the polyhedral Co-Fe-O nanoparticles) and

153 be a novel two step method to construct gold-nanorod functionalized polydiacetylene (PDA) microtube f

154 cancer cells with goserelin-conjugated gold nanorods (gGNRs) promotes gonadotropin releasing hormone

155 An innovative gold nanorod (GNR) array biochip was developed to systematica

156 thiolated pH-responsive DNA conjugated gold nanorod (GNR) was developed as a multifunctional nanocar

157 l predictions for gold nanospheres (GNS) and nanorods (GNR).

158 rties, tunability and biocompatibility, gold nanorods (GNRs) are being investigated as multifunctiona

159 based on thiolated probe-functionalized gold nanorods (GNRs) decorated on the graphene oxide (GO) she

160 zed surface plasmon resonance (LSPR) of gold nanorods (GNRs) is attractive for label-free biosensing.

161 switchable, light-dependent effects of gold nanorods (GNRs) on paramagnetic properties of nitroxide

162 103-nm gold nanoparticles (GNPs), 40-nm gold nanorods (GNRs), and 80-nm silver nanoparticles (SNPs) w

163 sensing weakly constrained diffusion of gold nanorods (GNRs).

164 hermal therapy of anti-CD11b Abs-linked gold nanorods (GNRs-CD11b) are combined to treat the carcinom

165 , GNPs; silver nanoparticles, SNPs; and gold nanorods, GNRs) were imaged and sliced in the z-directio

166 ntal data provide critical insights into the nanorod growth mechanism and unequivocal evidence for a

167 soon as nanoparticle elongation appears, and nanorod growth takes place inside organized superlattice

168 Gold nanocages and nanorods had very different light to heat transduction e

169 Coatings of silver layer and zinc oxide nanorods have been carried out on the bare core fiber wi

170 Gd2O3:Eu(3+) nanorods have been characterized by studying its structu

171 owth of hierarchical supercrystals of cobalt nanorods have been studied by in situ tandem X-ray absor

172 One-dimensional nanostructures, for example nanorods, have been shown spectroscopically to display i

173 eatly tuned by changes in inter-rod gaps and nanorod heights while the influence of the nanorod diame

174 e of plasmonically active silver-coated gold nanorods (henceforth referred to as plasmonic nano vecto

175 we show how both goals can be achieved in a nanorod heterostructure with type-II band offsets.

176 Four distinct classes of VO2 -TiO2 -VO2 nanorod heterostructures are accessible by modulating th

177 Hierarchical NiCo2O4 hollow nanorods (HR) were directly grown on stainless steel via

178 an be developed to the point where different nanorods in a mixture simultaneously report on the conce

179 ation treatment of solution-based beta-FeOOH nanorods in Ag precursor solution followed by high tempe

180 tion of cholesteric liquid crystal formed by nanorods in spherical droplets.

181 nstrating anisotropic silica coating of gold nanorods in which silica is deposited only on the sides

182 ion of Se precursors to the partially etched nanorods in Zn oleate solution can lead to epitaxial gro

183 ng liquids by in-situ heating metallic glass nanorods inside a transmission electron microscope.

184 studies demonstrate the high accumulation of nanorods into HeLa cells whereas viability analysis supp

185 When the nanorod is annealed, we observe with atomic-scale resolu

186 via coherent transformation dislocation; the nanorod is reduced to hafnium on cooling.

187 The LPG response of 21% for pristine TiO2 nanorods is enhanced to 49% after Pd catalyst decoration

188 in uniform, one-dimensional brookite titania nanorods is highly enhanced by engineering their length.

189 ulfur and hydrocarbons to the surfaces of Ag nanorods is observed when they are stored in ambient ove

190 A mechanism for the formation of the nanorods is proposed.

191 tu electrochemical sizing of individual gold nanorods is reported.

192 y photoluminescent imaging with Gd2O3:Eu(3+) nanorods is that this ultrafine nanorod material exhibit

193 A further increase in the nanorod length leads to a decrease in the THz pulse ener

194 identify unique contrast agents: large gold nanorods (LGNRs).

195 all-solution-processed double-heterojunction nanorod light-responsive light-emitting diodes open feas

196 Photoresponsive hybrid gold nanorod-liquid crystalline matrices were prepared and lo

197 We report unexpected inter-nanorod lithium-ion transport, where the reaction fronts

198 A gold nanorod-locked nucleic acid nano-biosensor for dynamic s

199 Gd2O3:Eu(3+) nanorods is that this ultrafine nanorod material exhibits hypersensitive intense red emi

200 This electrically driven plasmonic nanorod metamaterial platform can be useful for the deve

201 Here we show that in plasmonic nanorod metamaterials, the Kerr-type nonlinearity is not

202 te by measuring the diffusion coefficient of nanorods modified with the appropriate enzyme.

203 hexagonal-cubic core-shell architecture with nanorod morphology, the concentric CdS nanorod phase jun

204 he effect of PEGylation of mesoporous silica nanorods (MSNR) on hemolysis, colloidal stability, mitox

205 Gold nanorods (nano Au) deposited onto pencil graphite electr

206 Gold nanorods (nano Au) prepared were characterized by TEM an

207 Such conjugated polymer/plasmonic nanorod nanocomposites may find applications in fields,

208 fying concepts of 1D-photoanodes (nanotubes, nanorods, nanofibers, nanowires) based on titania, hemat

209 dopted for synthesizing Ta2O5 nanoparticles, nanorods, nanotubes and nanowires while Ta2O5 nanofibers

210 hesize extended gold nanostructures, such as nanorods, nanowires and nanosheets, with nanosecond coal

211 report on the development of Ni-shielded ZnO nanorod (NR) structures and the impact of the Ni layer o

212 ZnO nanorods (NRs) are known for ultra-sensitive biomolecule

213 Tin oxide nanorods (NRs) are vapour synthesised at relatively lowe

214 es (NPs) in the presence of 40 x 5 nm WO2.72 nanorods (NRs) for the synthesis of AgPd/WO2.72 composit

215 colloidal one-dimensional (1D) semiconductor nanorods (NRs) offer the opportunity to simultaneously m

216 When anisotropic semiconductor nanorods (NRs) were used as the fluorescent probes, the

217 nable from highly monodisperse nanocubes, to nanorods (NRs) with variable aspect ratios, and finally

218 ticles are constituted by the aggregation of nanorods of akaganeite.

219 Specifically, nanorods of AR 2.6 and 4.5 were assembled onto thiol-ter

220 In CdS nanorods of non-uniform width, we observe the recombinat

221 we present solar cells fabricated from PbSe nanorods of three different bandgaps.

222 es the arrangement of spatially varying gold nanorods on a flexible, conformable epoxy resist membran

223 ion and rotational information of the hybrid nanorods on synthetic lipid bilayers and on live cell me

224 ercome such challenge, we propose to form Ti nanorods on their surface to promote the new bone format

225 attainable even using confined nanocrystals, nanorods or nanowires.

226 dipoles placed in the gap between a metallic nanorod, or nanosphere, and a metallic substrate.

227 ed by the spatial arrangement of neighboring nanorod pair.

228 S) nanocrystals, causes end-to-end fusion of nanorod pairs into nanodumbbells at high yield.

229 vesicles ( approximately 60 nm) (AuNR = gold nanorod; PEG = poly(ethylene glycol); PLGA = poly(lactic

230 with nanorod morphology, the concentric CdS nanorod phase junctions (NRPJs) obtained demonstrate ext

231 scale engineering of surfaces in the form of nanorod-polymer composites.

232 c strategy toward the intriguing hydrocarbon nanorod polytwistane is outlined.

233 evation angles of anisotropic plasmonic gold nanorod probes in live cells.

234 wo Au nanoparticles at both ends of each CdS nanorod) provide more convincing high-resolution single-

235 lowed by contraction along the nanosphere or nanorod radial direction driven by a transient carrier-i

236 ncrement from the nanoparticle radii and ZnO nanorod random curving gives raise an enhancement in det

237 The CdSe/CdSe(x)Te(1-x) heterojunction-nanorod sensitized solar cell exhibits ~33% improvement

238 New hybrid materials consisting of ZnO nanorods sensitized with three different biomass-derived

239 consider a such CDSD made of two dissimilar nanorods separated by a thin but finite potential barrie

240 Ps are high surface area macromolecules with nanorod structures constructed from helical arrangements

241 ectives provide high quality fits across all nanorods studied, others show significant aberrations an

242 shape of ellipsoidal magnetic nanoparticles (nanorods) subjected to an external AC magnetic field: fi

243 ing of the infrared transmission of a hybrid nanorod suspension using an external magnetic field.

244 By virtue of these merits, the anatase nanorods synthesized in this work take obvious advantage

245 For copper nanorod targets with a length of 5 mum, a maximum 13.8 t

246 ximum energy enhancement of 28 times for the nanorod targets with a length of 60 mum.

247 ich are efficiently enhanced with the use of nanorod targets.

248 ibute this to the lack of nuclei in small MG nanorods that approach the nucleation length, thus coine

249 ports a degradation mechanism of silver (Ag) nanorods that are used as substrates for surface enhance

250 ce to the dense c-axis self-assembled BaZrO3 nanorods, the elimination of large misoriented grains, a

251 t streptavidin previously conjugated to gold nanorods, the LSPR shift is 26-fold enhanced.

252 such as geometric difference between the two nanorods, their volumes and the barrier width on quality

253 etics, we can tune the number of nuclei in a nanorod, thereby tailoring the resulting crystallization

254 le electron extraction at the heterojunction nanorod-TiO(2) interface.

255 and approximately half the gold mass of gold nanorods to achieve the same heating profile given a con

256 with variable morphologies from shuttle-like nanorods to microflowers by controlling the reaction tem

257 so imaged after a systemic injection of gold nanorods to observe their passive accumulation in the re

258 iffusion coefficient of the oxidase-modified nanorods to the concentration of the oxidase substrate,

259 the quantum dynamics of electrons inside the nanorods under a periodic optical perturbation that are

260 mall gaps are formed between adjacent silver nanorods upon solution evaporation.

261 LaF3 nanodisks and one-dimensional CdSe/CdS nanorods via liquid interfacial assembly.

262 -3 nm thickness was formed along alpha-Fe2O3 nanorods via ultrasonication treatment of solution-based

263 ea measurements of pristine TiO2 and Pd:TiO2 nanorods was examined by high resolution transmission el

264 Luminescence from gold nanorods was imaged with four different objectives to me

265 ing performance of pristine TiO2 and Pd:TiO2 nanorods was investigated in different LPG concentration

266 al methods and immobilized on rutile titania nanorods was investigated using aberration-corrected sca

267 The PPy segment of such nanorods was then modified with glucose oxidase (GOx), g

268 of bismuth oxide (Bi2O2.33) nanostructures (nanorods) was developed.

269 defined model system of cadmium sulfide-gold nanorods, we address the effect of the gold tip size on

270 These BiO nanorods were cast onto mass disposable graphite screen-

271 paramagnetic characteristic of Gd2O3:Eu(3+) nanorods were compared with the spherical nanoparticles

272 Gold nanorods were functionalized via polyethylene glycol wit

273 d the anisotropic optical properties of gold nanorods were maintained.

274 Polyhedral ceria and nanorods were more effective than ceria cubes at anchori

275 The resulting TiO2 nanorods were organized into microboxes that resemble th

276 In this study, hierarchical FeOF nanorods were synthesized through a facile, one-step, we

277 In present work, gold nanorods were used for amplification of electrochemical

278 ny small gaps are formed between adjacent Ag-nanorods, where "hot spots" are generated.

279 -ion transport within and between individual nanorods, where the impact of oxygen deficiencies is del

280 shaped antennas consisting of two orthogonal nanorods which lengths and coupling strength can be inde

281 from two different sizes of nanodisks and a nanorod, which offers the unique opportunity to design m

282 ed the catalytic potential of palladium-gold nanorods, which can be employed as nanozyme for developi

283 ) via 805 nm femtosecond pulses through gold nanorods whose localized surface plasmon resonance overl

284 onal phase of isomorphous ZrO2, has produced nanorods with a twinned version of the room temperature

285 e bundles are composed of several individual nanorods with diameter of 100 nm and length in the rang

286 We compare the performance of nanorods with equivolume nanoparticles of other shapes s

287 emonstrated this concept in cadmium selenide nanorods with gold tips, in which the gold plasmon was s

288 on and forms a porous network, imparting the nanorods with high mechanical strength and polarization-

289 ted only on the sides by functionalizing the nanorods with poly(ethylene glycol) methyl ether thiol (

290 aces, which consist of an array of plasmonic nanorods with spatially varying orientations, have shown

291 n exchange (CE) in core/shell Cu2-xSe/Cu2-xS nanorods with two cations, Ag(+) and Hg(2+), which are k

292 ng an array of electrically driven plasmonic nanorods with up to 10(11) tunnel junctions per square c

293 is used to mass produce free-standing silver nanorods with very high aspect ratios of more than 200 u

294 inding the center in asymmetric cases (i.e., nanorods) with high precision and accuracy.

295 luminomagnetic Gd2-xEuxO3 (x = 0.05 to 0.5) nanorod, with a diameter of ~20 nm and length in ~0.6 mu

296 Nanorods, with a Pt and a polypyrrole (PPy) segment, wer

297 results in reproducible formation of shaped nanorods, with independent control over their density an

298 We developed nickel-capped zinc oxide nanorod (ZnO/Ni NR) structures by e-beam evaporation of

299 mmunosensors based on one-dimensional 1D ZnO nanorods (ZnO-NRs) and two-dimensional 2D ZnO nanoflakes

300 lopment of immunosensor photoluminescent ZnO nanorods (ZnO-NRs) were deposited on glass substrate.