ライフサイエンスコーパス: nanostructure

1 ght and 90 degrees corner sections of the Py nanostructure.

2 function of light harvesting in a polymeric nanostructure.

3 the incorporation of every strand into a DNA nanostructure.

4 both properties can be realized in the same nanostructure.

5 tural and functional space of supramolecular nanostructures.

6 practical utilization in NRET-coupled hybrid nanostructures.

7 een the crystal structure and supramolecular nanostructures.

8 active building block for assembling modular nanostructures.

9 hus be used to electrically probe biological nanostructures.

10 processing route for Bi2 Te2.5 Se0.5 hollow nanostructures.

11 alable manufacturing of patterned-functional nanostructures.

12 maximum sensitivity amongst the synthesized nanostructures.

13 owed by the deposition of XO entrapped Ta2O5 nanostructures.

14 controlled preparation of polymer micro and nanostructures.

15 3.8% biaxial tensile strain in the germanium nanostructures.

16 izing and interpreting phonon propagation in nanostructures.

17 transformation into 3D structurally deformed nanostructures.

18 l hairpin assembly to form four-way junction nanostructures.

19 nsions like zero-, one- or three-dimensional nanostructures.

20 g procedure to form fibril-like and granular nanostructures.

21 nables the formation of functional plasmonic nanostructures.

22 tween quenching and enhancement by the metal nanostructures.

23 hould be extensible to a wide variety of DNA nanostructures.

24 otodetectors made of bottom-up semiconductor nanostructures.

25 diffraction confinement assisted by metallic nanostructures.

26 les for programmed self-assembly of discrete nanostructures.

27 to-edge packing by tailoring the size of DNA nanostructures.

28 e surface modified with M13 viruses and gold nanostructures.

29 l and irradiation-based etching of preformed nanostructures.

30 zes similar to that of a bacterium using DNA nanostructures.

31 ng in high local optical fields of plasmonic nanostructures.

32 ross-sectional strain analysis of complex 1D nanostructures.

33 result from the formation of supramolecular nanostructures.

34 proved the complexity and scalability of DNA nanostructures.

35 atially confined surface and bulk phonons in nanostructures.

36 the unique physical nature of these quasi-1D nanostructures.

37 nt electromagnetic fields on the surfaces of nanostructures.

38 s or propagating plasmons in patterned metal nanostructures.

39 over the dimensions and dispersity of these nanostructures, allowing access to uniform morphologies

40 The glycopeptide nanostructures amplified signalling of bone morphogeneti

41 magnetic properties using ferromagnetic (FM) nanostructures, an opportunity of manipulating antiferro

42 e spectral reflectance from this subcellular nanostructure and devise a new label-free technique base

43 ed with a sufficient balance between ordered nanostructure and fibril entanglement.

44 Benefiting from the unique porous holey nanostructure and high catalytic activity of the cathode

45 In combination, the corn-like nanostructure and the protective PDA coating contributed

46 and chemical properties that arise from the nanostructured and material characteristics of nanoparti

47 Well-controlled nanostructures and a high fraction of Sn/Li2 O interface

48 ally control the interface between synthetic nanostructures and biological systems.

49 wth allows the design of new core/multishell nanostructures and enables independent investigations of

50 I shielding materials, owing to their unique nanostructures and extraordinary electronic properties.

51 peptides were used as additive to deposit Au nanostructures and it is compared with the structure and

52 n be extended to other metal and metal oxide nanostructures and its application might be useful to de

53 Phonon scattering by nanostructures and point defects has become the primary

54 onsider four different types of chirality in nanostructures and related physical, chemical, and biolo

55 al imaging of individual magnetic molecules, nanostructures and spin-labelled biomolecules.

56 rveys novel achievements in the field of MIP nanostructures and their application for determination o

57 archers working on the growth of metal oxide nanostructures and their application in functional devic

58 deleterious sources of noise in solid-state nanostructures, and even a single trapped charge can qua

59 tructing complex and replicable nucleic acid nanostructures, and expands the design space and materia

60 rials palette, optimally designed micro- and nanostructures, and tightly regulated processes, nature

61 ged Rebar Graphene (BRG) onto newly designed nanostructured aptasensor for label free impedimetric se

62 Gradient nanostructures are attracting considerable interest due

63 The MZO nanostructures are chosen for their multifunctionality,

64 is also proceeding as new types of ultrathin nanostructures are constantly being created, such as met

65 Nitride epitaxial layers periodically, these nanostructures are expected to have comparable optoelect

66 n the other hand, metal-semiconductor hybrid nanostructures are found to be very promising for photon

67 Within cells, nanostructures are often organized using local assembly

68 These nanostructures are studied by scanning electron microsco

69 Most TMD alloy nanostructures are synthesized as films on substrates us

70 Mostly gold nanostructures are widely employed to this aim, but grea

71 bstrate including the fabrication of polymer nanostructure arrays and the metallization of the polyme

72 arrays and the metallization of the polymer nanostructure arrays.

73 The nanostructured arrays were fabricated by focused ion bea

74 Nanostructured artificial receptor materials with unprec

75 on, and offers a new approach to engineering nanostructures assembled from rod-coil block copolymers.

76 fferent DNA strands allows one to synthesize nanostructure assemblies that would be difficult to real

77 In-situ formation of Cr7C3 nanostructures at the MWCNT/Cu interface by reaction of

78 pment of a novel three dimensional manganese nanostructures based carbon nanotubes (CNTs-Mn NPs) comp

79 An organic-inorganic hybrid core-shell nanostructure, based on mesoporous silica coated upconve

80 Nanostructure-based plasmonic biosensors have quickly po

81 The resulting nanostructures bear split parts of DNAzyme at each end o

82 etic electrons through plasmon excitation of nanostructures before thermalization has been proposed f

83 mechanism for the formation of these ordered nanostructures being the two-dimensional diffusion of se

84 gh throughput technique capable of producing nanostructure (below 100 nm feature size) arrays, relies

85 Samples of nanostructured beta-Ga wires were synthesized by a novel

86 3D porous nanostructures built from 2D delta-MnO2 nanosheets are a

87 ding protein-specific binding domains to DNA nanostructures can be used to rationally control the int

88 Non-magnetic colloidal nanostructures can demonstrate magnetic properties typic

89 Nanostructured ceria becomes profoundly more active due

90 developments in low-temperature synthesis of nanostructured ceria, facilitating its large-scale manuf

91 Here we demonstrate that DNA nanostructures coated by oligolysines to 0.5:1 N:P (rati

92 Proteins bound within the nanostructured coatings demonstrate enhanced stability a

93 high density of single-crystalline germanium nanostructures coherently embedded in InAlAs without ext

94 First, major classes of nanostructured components, both inorganic reporters and

95 oxygen biofuel cell based on transparent and nanostructured conducting supports.

96 ively studied as a short-period superlattice nanostructure consisting of ultra-thin III-Nitride epita

97 germanium, we report here a complex gradient nanostructure consisting of, near the surface, nanocryst

98 Meanwhile, Co-doping in FeOOH nanostructures constitutes a desirable four-electron pat

99 digestates of the proportion of amorphous or nanostructured copper sulfides as well as amorphous or n

100 l morphology such as spherical and fibrillar nanostructures could be controlled by adjusting the rod-

101 ic aromatic hydrocarbons (PAHs) and graphene nanostructures demand methods that are capable of select

102 Here, we show subwavelength thermoelectric nanostructures designed for resonant spectrally selectiv

103 oscopy of picoliter-volume solutions using a nanostructured diamond chip with dense, high-aspect-rati

104 Kehayias et al. present a nanostructured diamond grating with a high density of NV

105 Diamond based materials, and specifically nanostructured diamond has attracted much attention due

106 s, but in many device architectures they are nanostructured, disordered and buried away from the surf

107 e of solvophobic sequestration of water into nanostructured domains around cholinium cations.

108 how fluid stresses can affect different DNA nanostructures during LC purification and suggest that s

109 remarkable practical utility by preparing a nanostructured earth abundant metal catalyst which rival

110 cteria-DNA interactions were captured on BRG nanostructured electrode by using specific anti-E.coli D

111 cult to adapt to the spatially heterogeneous nanostructured electrode materials that are now commonly

112 cium verrucaria was immobilized onto the ITO nanostructured electrode surface under formation of a bi

113 pports resulting in a flocculent, porous and nanostructured electrode surface.

114 ing of arrays of Troponin functionalized ZnO nanostructure electrodes.

115 crease in number of CPT units, the resulting nanostructures exhibited a morphological transformation

116 The assembly of such nanostructures exhibits a relatively low surface-to-volu

117 Resonantly excited, such metal nanostructures feature collective oscillations of electr

118 iochemical DNA nanoscopy method that records nanostructure features in situ and in detail for later r

119 The efficacy of dichroic targeting of chiral nanostructures for biomedical applications is exemplifie

120 ations play in designing effective polymeric nanostructures for biomedical applications.

121 ation of functional organic/inorganic hybrid nanostructures for diverse optoelectronic applications.

122 exciton dissociation mechanism and to design nanostructures for effective charge separation.

123 des low-cost and effective protection of DNA nanostructures for in vivo applications.

124 We demonstrate the utility of these nanostructures for photocatalytic chemical reactions in

125 discuss the significance of porphyrin-based nanostructures for potential light-harvesting systems.

126 aN digital alloy (DA) is a superlattice-like nanostructure formed by stacking ultra-thin ( </= 4 mono

127 Furthermore, we reveal distinct SEI nanostructures formed in different electrolytes.

128 r for convenient and accurate detection, the nanostructured FRET sensors were assembled onto a patter

129 ethod is based on replication of overhanging nanostructures from an aluminum tube template to polydim

130 rification promises to provide insights into nanostructure-function relationships.

131 y open up a new avenue in the fabrication of nanostructure functionalized polymeric membranes for was

132 This 3D nanostructured gel-based framework represents a powerful

133 ncement are reviewed including the choice of nanostructures geometries, arrangements, and materials.

134 The biofunctionality of these plasmonic nanostructures has been demonstrated by fluorescent micr

135 through implementation of surface micro- and nanostructures has gained substantial interest in recent

136 egies for the selective functionalization of nanostructures have been developed despite their potenti

137 any methods for self-assembling biomolecular nanostructures have been developed, few can be programme

138 Furthermore, multishell rod-like nanostructures have been prepared with optically active

139 In more recent times, these nanostructures have found interesting applications as ad

140 Surfaces with metal oxide nanostructures have gained considerable interest in appl

141 Self-assembled peptide and protein amyloid nanostructures have traditionally been considered only a

142 rganic heterostructures, and porphyrin-based nanostructures, have been highlighted in this review.

143 s in their native environment by prospective nanostructures holds much promise for real-time, accurat

144 Electronic doping of colloidal semiconductor nanostructures holds promise for future device concepts

145 In nanostructures, however, spatial confinement can cause h

146 gation) an attractive method for fabricating nanostructured hybrid films with potential applications

147 th concurrent design to produce quasi-random nanostructures in amorphous silicon at wafer scales that

148 ly been used to image plasmonic behaviour in nanostructures in an electron microscope, but hitherto i

149 ed the potential in integrating nucleic acid nanostructures in cells and in vivo where they can perfo

150 eficial yet challenging to synthesize hollow nanostructures in large quantities, with high porosity,

151 , macro defect-free colloidally assembled 3D nanostructures in the form of silk inverse opals (SIOs)

152 s solvent, achieving precise control over 1D nanostructures in water, an essential feature for any re

153 Here we show that hybrid core-shell nanostructures in which a core plasmonic metal harvests

154 Nanostructure-initiator mass spectrometry (NIMS) is a la

155 lly driven CE reaction to prepare individual nanostructures inside a transmission electron microscope

156 The anchor-like, nanostructured interface between PZT and Metglas, improv

157 So instead of just a nanostructured intermediate to be calcined, lithium tita

158 merging electronic dopant in III-V and II-VI nanostructures, introducing intragap electronic states o

159 Particular attention will be given to hybrid nanostructures involving graphene and other graphene-lik

160 odynamically less favorable core-shell Ag@Au nanostructure is kinetically stabilized by the intermedi

161 However, the DES nanostructure is retained to a remarkably high level of

162 e oxidation of ascorbic acid by the designed nanostructures is a diffusion control mechanism.

163 t how the formation and maintenance of these nanostructures is coordinated with the growth and develo

164 lizing such positional disorder of identical nanostructures is difficult, which in turn has limited e

165 different states.The spatial organisation of nanostructures is fundamental to their function.

166 ss in the development of highly active oxide nanostructures is hampered by a lack of knowledge of the

167 or heterostructures based on layered V2 -VI3 nanostructures is investigated by means of density funct

168 Optical excitation of nanostructures is known to induce local heating, a pheno

169 The field of chiral inorganic nanostructures is rapidly expanding.

170 A spontaneous self-organization of these nanostructures is then triggered to form stable hybrid m

171 o map vibrational modes directly in a single nanostructure, limiting our understanding of phonon coup

172 dy reports a drug delivery system comprising nanostructured lipid carrier (NLCs) within liposomes (Li

173 In this work, EGCG-loaded nanostructured lipid carriers (NLC) functionalized with

174 vent, the ability to tune the 3D cubic phase nanostructure, lipid bilayer properties and the lipid me

175 Simultaneously, synthesized nanostructures maintain immunomodulatory properties, des

176 ation of efficient sensor platforms based on nanostructures make the highly sensitive sensors which c

177 Nanostructured manganese oxides, e.g. MnO2, have shown l

178 It reveals that the nanostructured material with plasmonic nanobiosensor pav

179 Silica nanostructured materials are important in many fields, i

180 , for the development of stimuli-responsive, nanostructured materials for technological applications

181 Bimetallic, nanostructured materials hold promise for improving cata

182 elated research pertaining to amidoxime; and nanostructured materials such as metal-organic framework

183 re may also aid in modeling the synthesis of nanostructured materials through self-assembly of nanopa

184 Among the nanostructured materials, the carbonaceous material such

185 ry, their combination and consolidation into nanostructured materials, the strategies to electronical

186 tics and insecticides, to the fabrication of nanostructured materials, to the concentration and separ

187 le approach for the creation of a variety of nanostructured materials.

188 growth and stability of catalysts and other nanostructured materials.

189 w-cost ink based holographic phase-conjugate nanostructures may have applications in flexible and pri

190 apsulation of allergens or DNA vaccines into nanostructures may provide advantages compared to the co

191 ts of the studies relating to fabrication of nanostructured metal oxide (NMO) based cancer biosensor.

192 Nanostructured metal oxide semiconductors have shown out

193 Ultra-thin nanostructured metal-insulator-metal geometries result i

194 n a layer-by-layer fashion, biomolecules and nanostructures (metallic or not) may amplify the SPR sig

195 e design ultra-low stiffness in fully dense, nanostructured metals via the stabilization of a mechani

196 using the eSHHA approach in conjunction with nanostructured microelectrodes is an advantageous altern

197 We demonstrated that eSHHA on nanostructured microelectrodes leverages three effects:

198 roblast growth factor (bFGF) released from a nanostructured mineral coating maintains its biological

199 ular attention has been paid to syntheses of nanostructured MIP films and MIP nanoparticles.

200 The new-designed nanostructures must be carefully studied and well charac

201 concept of SERS hot spots and the plasmonic nanostructures necessary for SM detection, the past and

202 It has been demonstrated that the nanostructures not only are beneficial to the mechanical

203 Nanostructured (NS) and ultrafine-grained (UFG) material

204 or characterization of free and enzyme bound nanostructures (NS).

205 minant release channel of electronic heat in nanostructures, occurs with characteristic times of seve

206 The nanostructure of a series of choline chloride/urea/water

207 Inspired by the highly ordered nanostructure of bone, nanodopant composite biomaterials

208 The self-assembled nanostructure of OEGCG combined with lycopene may be a p

209 e characterized the accurate composition and nanostructure of this chloride-rich phase by using micro

210 Nanostructures of layered transition metal dichalcogenid

211 t of xanthine oxidase (XO) enzyme in several nanostructures of tantalum (v) oxide (Ta2O5) have been r

212 ad to fast and automated purification of DNA nanostructures of various shapes and sizes, which would

213 is, water promotes structural diversity and nanostructuring of compounds, but does not necessarily d

214 Nanostructuring of magnetically hard and soft materials

215 In particular, nanostructuring of semiconductors can lead to strong sup

216 One dimensional (1D) nanostructures offer prospects for enhancing the electri

217 mon resonance (SPR) sensor in a checkerboard nanostructure on plastic substrates is presented for dig

218 hodology for preparation of Cu@Pd core-shell nanostructures on a cost-effective pencil graphite subst

219 re, we develop flat and thin phase-conjugate nanostructures on low-cost ink coated glass substrates t

220 ment, offers the ability to grow metal oxide nanostructures on most of the metals in the periodic tab

221 wide variety of metals can form metal oxide nanostructures on their surfaces after simply interactin

222 ng coatings of silver and graphene doped ZnO nanostructure onto the unclad core of the optical fiber.

223 d spontaneous concentration of the resulting nanostructures onto SiO2 particles mediated by the silic

224 gned by selective hydrothermal growth of ZnO nanostructures onto the working electrodes of polyimide

225 ontrol of the gigahertz response of metallic nanostructures, opening the door to new optomechanical d

226 oes not disrupt the filamentous shape of the nanostructures or their internal beta-sheet backbone, bu

227 , impulsive electromagnetic stimulation, and nanostructuring or interface engineering.

228 -thin high-k dielectric layer (Al2O3) with a nanostructured organic functional tail to create a platf

229 Our new approach using nanostructured phase transformation provides new opportu

230 t the properties of dual emission and single-nanostructure photostability depend on different structu

231 array on slides coated with a noncontinuous, nanostructured plasmonic gold film, enabling quantitativ

232 e synthesis of bulk crystals, thin films and nanostructures plays a seminal role in expanding the fro

233 with the structure and reactivity of the Au nanostructures prepared in the presence of M134E.

234 Thus, these novel carbon nanostructures provide an interesting concept for develo

235 A comparative study of nanostructured PuO2 and Pu colloids produced by sonochem

236 le of plasmonic "hot spots" within the metal nanostructures, remain poorly understood.

237 DNA nanostructures represent the confluence of materials sci

238 A fundamental question is how hydrophilic nanostructures reside in the hydrophobic environment of

239 rown around antibodies anchored to plasmonic nanostructures serves as a protective layer to preserve

240 rgy into catalytically active centres on the nanostructure shell.

241 etween the conventional and phase-conjugated nanostructures showed two-fold increase in diffracted li

242 The photocurrent of the nanostructures shows an NADH-dependent magnitude.

243 The designed metasurface consists of nanostructured silver and indium tin oxide (ITO) electro

244 water molecules from the hydration shells of nanostructured solutes and calculate the free energetics

245 l cover both experiment and theory of chiral nanostructures starting with the origin and multiple com

246 electrochemical genosensors based on carbon nanostructures such as carbon nanotubes, graphene, graph

247 amic compression to synthesize extended gold nanostructures, such as nanorods, nanowires and nanoshee

248 Progress in the synthesis of boron nanostructures suggests that the predicted unusual behav

249 elength, high-refractive index semiconductor nanostructures support optical resonances that endow the

250 zymatic fuel cell, as a result of the higher nanostructured surface area as confirmed by electrochemi

251 I) was reduced and deposited as As(0) on the nanostructured surface by applying a potential of -0.3 V

252 en-oligonucleotide probes immobilized on the nanostructured surface.

253 etection limit of eSHHA, taking advantage of nanostructured surfaces to allow the use of longer captu

254 Nanostructured surfaces with quasi-random geometries can

255 Oligolysine-PEG-stabilized DNA nanostructures survive uptake into endosomal compartment

256 Such processes combined with graphene-nanostructure synthesis has the potential to create comp

257 ompared with the large variety of solid gold nanostructures, synthetic approaches for their hollow co

258 Nanostructured systems have the potential to revolutioni

259 block for the programmable self-assembly of nanostructured systems-was to use DNA to construct three

260 e we report the design of an interlocked DNA nanostructure that is able to fine-tune the oxidative ca

261 esents a dynamic continuum of supramolecular nanostructures that selectively inhibits cancer cells vi

262 s into the structures of colloidal TMD alloy nanostructures that were previously only accessible for

263 optical phenomena associated with plasmonic nanostructures, the scope for use in reflective pixel te

264 These nanostructured thin COF films demonstrate remarkable sol

265 e authors demonstrate how a CMOS-compatible, nanostructured, thin junction structure can make use of

266 tigated by synthesizing catalytically active nanostructured TMDs in bulk quantity using a liquid-base

267 assembling multiple monolayers of different nanostructures to achieve various tunable desired proper

268 Here we propose the use of semiconductor nanostructures to create a type-II heterojunction at the

269 allows manipulation of the shape and size of nanostructures to create geometries potentially useful f

270 We assay our approach using DNA origami nanostructures to quantitatively assess labeling, imagin

271 sis technique based on the vaporization of a nanostructure-trapped liquid "initiator" phase.

272 The incorporation of these nanostructures triggered improvements in the short circu

273 Nanostructures underpin the excellent properties of silk

274 self-assembly has produced complex synthetic nanostructures, unimolecular folding has seen limited pr

275 dendritically assemble into highly branched nanostructure upon introducing a trigger sequence.

276 sis of micellar spherical nucleic acid (SNA) nanostructures using Pluronic F127 as a thermoresponsive

277 ethod for surface characterization of silica nanostructures, using widely available NMR spectroscopy

278 ions, often gallium (Ga(+)), FIB can sculpt nanostructures via localised sputtering.

279 new PVP capped CoFe2O4@CdSe with core-shell nanostructure was synthesized by a facile synthesis meth

280 Formation of core-shell type nanostructures was confirmed by transmission electron mi

281 gated diffraction property from the recorded nanostructures was verified through spectral measurement

282 The synthesized Ta2O5 nanostructures were characterized by photoluminescence,

283 nce (PL) spectra and UV-vis spectra of these nanostructures were studied.

284 The nanostructures were subsequently utilized to create mast

285 Two different procedures for surface nanostructuring were employed, viz.

286 ich enable the efficient growth of dendritic nanostructures, whereas such dendritic structures were n

287 ersatile platform for preparing well-defined nanostructures wherein functionality such as catalysis c

288 C60-serPF) was designed to be an amphiphilic nanostructure, which is able to cross several biological

289 en chiral inorganic, organic, and biological nanostructures will also accelerate the development of t

290 The release of O2 creates a hollow nanostructure with Li2O outer-shell and Li2O2 inner-shel

291 hey were able to self-assemble into lamellar nanostructures with alternating IgG and poly(N-isopropyl

292 logous host organisms, functionalizing these nanostructures with moieties for targeting and fluoresce

293 ced by depositing 130.5nm thin layer of SiO2 nanostructures with particle size lesser than 70nm.

294 The ring-shaped nanostructures with surrounding graphene walls are stabl

295 ing pathways that may aid the design of soft nanostructures with tunable dynamic properties and life

296 Large-scale fabrication of precisely defined nanostructures with tunable functions is critical to the

297 Since, nanostructured WO3 is a well known catalyst, the simulta

298 Yolk-shell nanostructures (YSNs) composed of a core within a hollow

299 ured copper sulfides as well as amorphous or nanostructured zinc sulfides and zinc phosphate as compa

300 resulting in the generation of high density nanostructure ZnO arrays based electrodes.