ライフサイエンスコーパス: nanoscale

1 roscopy (AFM) to perform measurements at the nanoscale.

2 al effort has been engaged for doping at the nanoscale.

3 surement of molecule-molecule interaction at nanoscale.

4 nces in the structure of the crystals at the nanoscale.

5 e for evaluating the ferroelectricity at the nanoscale.

6 on of the layer and tunnel structures at the nanoscale.

7 ay of excitons, phonons, and plasmons at the nanoscale.

8 amples with subdiffraction resolution at the nanoscale.

9 ic macromolecular caging and decaging at the nanoscale.

10 ol the magnitude and sign of chi((2)) at the nanoscale.

11 s of shuttles, switches, and machines at the nanoscale.

12 n understanding electronic properties at the nanoscale.

13 grammed to perform specific functions at the nanoscale.

14 h degree of motion design and control at the nanoscale.

15 of structures and functional devices in the nanoscale.

16 and physical properties are modified at the nanoscale.

17 tune the LaAlO3/SrTiO3 interface 2DEG at the nanoscale.

18 ch to manipulate SrTiO3-based devices on the nanoscale.

19 internal structures, and obtained the first nanoscale 10 KeV X-ray absorption images of the interior

20 effects: (1) steric hindrance effects at the nanoscale, (2) a size-dependent hybridization rate of DN

21 ogy of heterogeneous electrocatalysts at the nanoscale allows identification of active areas (protrus

22 t would photogenerate pulling forces, at the nanoscale and beyond.

23 We demonstrate that confinement at the nanoscale and direct interaction with the charged interf

24 is able to differentiate composition on the nanoscale and enables in-depth studies into the relation

25 es, becoming a new tool for tribology on the nanoscale and has allowed the observation of the hithert

26 r a new strategy for chemical imaging at the nanoscale and has the potential to aid discovery of new

27 ocatalyst material developed with a combined nanoscale and molecular approach.

28 the evaluation of polarization charge at the nanoscale and provide a new guideline for evaluating the

29 as a function of the number of layers at the nanoscale and show in-depth how the band gap is affected

30 imulation results, resolved spatially on the nanoscale and temporally over time increments of fractio

31 atial heterogeneity in the porosity of OM at nanoscale, and bulk spectroscopy measurements have docum

32 initial tablet sliding primarily resisted by nanoscale aragonite pillars from the following sliding r

33 precision of 10-30 nm, revealing the cell's nanoscale architecture at the molecular level.

34 chemical composition but differing in their nanoscale architectures.

35 structive and structurally definitive on the nanoscale are in demand, especially for a detailed under

36 ach reveals that graphene derivatives at the nanoscale assemble into various architectures of nanocry

37 ein I show that, translated from the dynamic nanoscale assemblies in cell membranes known as lipid ra

38 approach for the formation of electrochromic nanoscale assemblies on transparent conductive oxides on

39 chirality transfer, polarization effects in nanoscale assemblies, and others.

40 hlighting the structural uniqueness of these nanoscale assemblies.

41 ith potential applications in nanomachinery, nanoscale assembly, fluidics, and chemical/biochemical s

42 alent nanomaterials, involving modulation of nanoscale backbone structures and number and spacing bet

43 Membrane nanopores-hollow nanoscale barrels that puncture biological or synthetic

44 or probing the shape properties of adsorbed, nanoscale biological particulates.

45 to explore the geometry-induced trapping of nanoscale biomolecules and examine a generation of surfa

46 lipid and CTxB diffusion was observed at the nanoscale bud locations, suggesting a local increase in

47 class of compounds that combine programmable nanoscale building blocks and atomic precision.

48 spholipid bilayers are not homogenous at the nanoscale, but specific ions are able to locally alter m

49 how control of anion and cation order at the nanoscale can be utilized to produce acentric structures

50 known mechanism for controlling shape at the nanoscale can lead to broader libraries of quasi-two-dim

51 for studying the properties of this form of nanoscale carbon materials.

52 Nanoscale carbon-rich molecular architectures are not on

53 Nanoscale carriers are able to deliver therapeutic radio

54 The nanoscale CC-ZIFs are biocompatible and easily scaled-up

55 The nanoscale cell is formed by bringing a Pt/TiO2-coated at

56 effect of decrease in ferrite grain size and nanoscale cementite.

57 Nanoscale cerium oxide is used as a diesel fuel additive

58 e additive Envirox, which utilizes suspended nanoscale cerium oxide to reduce particulate matter emis

59 These results highlight how nanoscale changes can induce reactivity in 2D materials,

60 Nanoscale changes to the cell wall during unmasking were

61 transport of single DNA molecules through a nanoscale channel is critical to DNA sequencing and mapp

62 a novel carrier-free theranostic system with nanoscale characteristics for near-infrared fluorescence

63 As a consequence, nanoscale characterization of the membrane has been perf

64 s mechanism has broad applicability to using nanoscale chemical reactors for surface redox reactions

65 Nanoscale chemically inhomogeneous surfaces comprising o

66 nciples may be used to design and understand nanoscale chiral phenomena and highlight important recen

67 ess the "lifetime" of hot-carrier gases with nanoscale circuits may provide a multitude of applicatio

68 2D nanoscale cloth will provide access to a new generation

69 stributed in a periodic array in the sample, nanoscale clustering is not observed, and the ReO4(-) an

70 Irradiation of nanoscale clusters and large molecules with intense lase

71 On the nanoscale, cobalt phthalocyanine (CoPc) molecules are un

72 In nanoscale colloidal systems, however, less is known abou

73 Nanoscale compartments are one of the foundational eleme

74 olled multiblock polymers in discrete stable nanoscale compartments via an emulsion polymerization ap

75 omplementary partners associate to produce a nanoscale complex and in other cases a ditopic host mole

76 Entanglement of nanoscale components in the network relies on weak short

77 s to understand how cells are assembled from nanoscale components into micrometer-scale entities with

78 chitectures, and the integration of multiple nanoscale components into multifunctional ordered nanost

79 intrinsic stiffness and rod-like geometry of nanoscale components limit the cohesive energy of the ph

80 oenvironments require careful engineering of nanoscale components that are highly sensitive, biorecog

81 rials, namely lattice structures composed of nanoscale constituents.

82 Thus, these nanoscale constructs open avenues for biomedical applica

83 Our results pave the way for nanoscale control and imaging of spin transport in mesos

84 r knowledge, stochastic nucleation events of nanoscale copper deposits are visualized in real time fo

85 mission electron microscopic analysis of the nanoscale crosspoint device suggests that elongation of

86 Nanoscale crystal growth control is crucial for tailorin

87 at the single-unit-cell level reveals novel nanoscale crystal-growth phenomena associated with the l

88 al for optimizing mechanical properties with nanoscale CTBs in material design.

89 Here we demonstrate self-assembly to nanoscale cuboidal particles with a bicontinuous cubic s

90 lectronic excitation under friction, and the nanoscale current-voltage spectra analysis indicates tha

91 h kinetics and shape evolution of individual nanoscale deep pits with estimates from macroscopic expe

92 to genome-free MS2 viral capsids, affording nanoscale delivery vectors that can target a variety of

93 tionalities that could be exploited in novel nanoscale device designs.

94 nanocomposites one step closer toward future nanoscale device integration.

95 e a route to controlling the DW behaviour in nanoscale device structures.

96 atchet, which may find applications in novel nanoscale devices, such as magnetic nanomotors, actuator

97 fashion, hindering the future integration in nanoscale devices.

98 mical sensing, drug delivery, catalysis, and nanoscale devices.

99 momentum transfer dependence pointing toward nanoscale diffusion.

100 with two-photon excitation microscopy to map nanoscale diffusivity in ex vivo brain slices.

101 Due to their nanoscale dimension(s), nano-barcodes have been implemen

102 intralayer biphase interfaces, and both have nanoscale dimensions.

103 and the ability to reliably pattern them in nanoscale dimensions.

104 the number of synaptic GABAA receptors, the nanoscale distribution of GABAA receptors in the postsyn

105 Nanoscale domains and fluctuations differ in several pro

106 show that accurate U-Pb isotopic analysis of nanoscale domains of baddeleyite can be achieved by atom

107 Ultimately, the nanoscale droplets flatten out to form layer-like molecu

108 n exploring this non-covalent interaction in nanoscale drug delivery systems for pharmaceutical agent

109 hts for the design of the next-generation of nanoscale drug delivery systems.

110 NSE can pinpoint the nanoscale dynamics changes in a highly specific manner.

111 t electrostatics modulates the activation of nanoscale dynamics of an intrinsically disordered protei

112 ect of intense investigation regarding their nanoscale dynamics with increasing interest in obtaining

113 concentration, correlating with the excited nanoscale dynamics.

114 The approach shows that three nanoscale effects are important and had to be incorporat

115 exciting both a fluorogenic reaction at the nanoscale electrode tip as well as fluorescent nanoparti

116 nts an enabling technology for the design of nanoscale electronic devices.

117 Bioelectronics moves toward designing nanoscale electronic platforms that allow in vivo determ

118 f 1D boron may find powerful applications in nanoscale electronics and/or mechanical devices.

119 However, progress in nanoscale electronics demands insulators just as it need

120 Our finding can enrich our understanding of nanoscale energy transfer in molecular excitonic systems

121 organized dye aggregates for use in coherent nanoscale energy transport, artificial light-harvesting,

122 cy (NV) color centers enables the probing of nanoscale ensembles down to approximately 30 nuclear spi

123 ques for characterizing molecular systems in nanoscale environments.

124 Here we combine nanoscale experiments with molecular-level simulation to

125 e monolayer is exploited to create arrays of nanoscale features using 'short' or 'extended' reactive

126 istribution varying locally as a function of nanoscale film morphology, ion concentration and potenti

127 The coloration intensities of these nanoscale films can be tuned by the number of deposition

128 ive to Do as desaturation progressed down to nanoscale films.

129 When tailored, this nanoscale flexoelectric effect enables a controlled spat

130 ttency or blinking is observed in nearly all nanoscale fluorophores.

131 Here we use nanoscale force measurements in combination with solid-s

132 Measurement of these nanoscale forces is a major challenge in cell biology; y

133 However, the molecular features and the nanoscale forces that control the interactions among cel

134 allic surface can trap optical fields in the nanoscale gap.

135 without HRE, a crystallographically textured nanoscale grain structure is ideal; and this conventiona

136 erogeneity of OM chemical composition at the nanoscale has been lacking.

137 ability to control electronic states at the nanoscale has contributed to our modern understanding of

138 owever, characterizing hydrophobicity at the nanoscale has remained a challenge due to its nontrivial

139 ehind these novel transport phenomena on the nanoscale have been explored in depth on single-pore pla

140 (8-16) require a thorough understanding of (nanoscale) heat flow.

141 room temperature, has been incorporated into nanoscale heterostructures through solution-phase epitax

142 On the nanoscale, however, gecko adhesion is shown to depend on

143 sed the PTIR throughput considerably, making nanoscale hyperspectral imaging within a reasonable time

144 Here, we combined a nanoscale imaging approach with advanced image analysis

145 ar cell imprinting platforms can be used for nanoscale imaging of cancer morphology, as well as to in

146 inically optimized form of ExM that supports nanoscale imaging of human tissue specimens that have be

147 scopic analysis of reflected light, enabling nanoscale imaging of myelinated axons in their natural l

148 e progress of experimental techniques at the nanoscale in the last decade made optical measurements i

149 Size-dependent phenomena at the nanoscale influence many applications, notably in the sc

150 n of the mechanically active rotaxane at the nanoscale influences the physical reticulation of the po

151 Herein, we describe a soft device that uses nanoscale information to mimic seedpod opening.

152 ing, which further permits dispersion of the nanoscale intermetallic onto a support.

153 Here, we combine nanoscale intracellular electrodes with complementary me

154 of the plasma membrane and the membranes of nanoscale intracellular organelles, a result we found to

155 ultraviolet has become an important tool for nanoscale investigations.

156 at while the study of stereochemistry on the nanoscale is a rich and dynamic area, our understanding

157 approach to achieving chemical mapping on a nanoscale is described that can provide 2D and tomograph

158 rigidity ranging from the micrometer to the nanoscale is described.

159 er associated with materials designed at the nanoscale is not simply a solvent, but rather an integra

160 magnetic fields with large gradients on the nanoscale is of fundamental interest in material science

161 of small plastic particles at the micro- and nanoscales is of growing concern, but nanoplastic has no

162 Electrochemically, the nanoscale ITIES supported by a rough nanotip gives highe

163 Here we demonstrate a nanoscale Kirkendall cavitation process that can transfo

164 icles to hollow metal oxide nanoshells via a nanoscale Kirkendall process-for example, coalescence of

165 solve fluorescently labeled molecules on the nanoscale, leading to many exciting biological discoveri

166 on microscopy (cryo-EM) can be used to image nanoscale lipid and polymer-stabilized perfluorocarbon g

167 cause they provide a relatively monodisperse nanoscale lipid bilayer environment for delivering membr

168 r nanotube sorting, on-chip passivation, and nanoscale lithography.

169 tion gap between the "gross" (>100s mum) and nanoscale (<1 mum).

170 driving force for molecular rotary motors in nanoscale machines.

171 ll reconstruction of all three components of nanoscale magnetic fields is possible without tilting th

172 on single spins in diamond is used to sense nanoscale magnetic fields with an intrinsic frequency re

173 In nanoscale magnetic resonance probes, for instance, finit

174 Progress in experimental techniques at nanoscale makes measurements of noise in molecular junct

175 ances in chemical synthesis have yielded new nanoscale materials with precisely defined biochemical f

176 y to control the complexity and hierarchy of nanoscale materials, and promises to create a diverse ra

177 CVD) process permits macro-scale assembly of nanoscale materials, enabling continuous production of c

178 ing ductility and strength simultaneously in nanoscale materials.

179 cules, other methods to impart handedness to nanoscale matter specific to inorganic materials were di

180 the negative Gaussian curvature neck of the nanoscale membrane buds.

181 tical imaging technique for the detection of nanoscale membrane curvature in correlation with single-

182 planar supported lipid bilayers than within nanoscale membrane curvature.

183 the high potential of these dyes for probing nanoscale membrane heterogeneity.

184 Extracellular vesicles (EVs) are nanoscale membrane-derived vesicles that serve as interc

185 Nanoscale metallic crystals have been shown to follow a

186 demonstrated represents a paradigm shift for nanoscale metamaterial and metasurface design.

187 In nanoscale metrology, dissipation of the sensor limits it

188 ehavior consenting material reshaping at the nanoscale, microscale, and macroscale.

189 applicability for the assembly of individual nanoscale moieties in array configurations with single-m

190 Through nanoscale morphological control, the sensitivities of th

191 w salt-concentration-dependent excitation of nanoscale motion at the tip of the C-terminal tail in th

192 t microscopy to result in full disclosure of nanoscale motions with high accuracy.

193 An analytical technique operating at the nanoscale must be flexible regarding variable experiment

194 raction of biological building blocks at the nanoscale, natural photonic nanostructures have been opt

195 roversial discussions about the molecular or nanoscale nature of many WOCs.

196 This nanoscale nolinear optical converter that simultaneously

197 computing will require very large numbers of nanoscale nonlinear oscillators.

198 Nanoscale nonuniformities in the PBAT films affected enz

199 s has a fascinatingly complex structure, yet nanoscale nonuniformities inherently present in polyamid

200 erhydrophilic surface property and excessive nanoscale nucleation sites created by the nanoporous sur

201 The increased forward scattering from nanoscale objects at this short wavelength has enabled u

202 Detection of nanoscale objects is highly desirable in various fields

203 ng approach to the fabrication of functional nanoscale objects with high shape anisotropy.

204 ilver concentration and restructuring at the nanoscale on oxidation activity is demonstrated.

205 be exploited to enhance the photoresponse of nanoscale optoelectronic devices.

206 D) superresolution microscopy to analyze the nanoscale organization of 12 glial and axonal proteins a

207 ity and chemical order, we relate the direct nanoscale origins of this memory effect to site disorder

208 cisely organizing functional elements at the nanoscale over a large solid surface area.

209 nometers or with dynamical information about nanoscale particle motion in the millisecond range, resp

210 variety of potential device applications.The nanoscale patterning of two-dimensional materials offers

211 ircuits requires significant advancements in nanoscale patterning technology.

212 n or cholera-toxin treatment, but found this nanoscale phase separation absent in native cells.

213 ing in higher T N in the parent, it promotes nanoscale phase separation in the superconductor resulti

214 l-Cu alloys to measure kinetics of different nanoscale phases in 3D, and reveals insights behind some

215 mentally implemented systems are governed by nanoscale physical processes that can lead to very diffe

216 t is confined and amplified at the apex of a nanoscale plasmonic probe, meets these criteria.

217 alloys can be correlated to the formation of nanoscale-platelets of beta1-Mg3Nd precipitates, that gr

218 ne through external mutagenesis and a unique nanoscale platform to study structurally related biologi

219 aptamer amphiphiles that self-assemble into nanoscale polymeric micelles with a densely functionaliz

220 At the micro- and nanoscales, polyvinyl chloride, polyethylene terephthala

221 These materials can sustain nanoscale pores in their rigid lattices and due to their

222 ructure and processes of living cells at the nanoscale poses a unique analytical challenge, as cells

223 dynamically and reversibly, positioned with nanoscale precision, and combined synergistically to con

224 l and spatial resolution to directly observe nanoscale processes.

225 al device performance and translating unique nanoscale properties to the macroscale.

226 Nanoscale protein ionic liquids represent multifunctiona

227 Herein, we report a nanoscale protein-sensing platform with a non-equilibriu

228 itro PPI interrogation technique, to perform nanoscale pulldowns (NanoSPDs) within living cells.

229 ses in neocortex, where it is organized into nanoscale puncta that influence the size of their associ

230 Here we report plasmon-induced formation of nanoscale quantized conductance filaments within metal-i

231 ciency in hot-carrier extraction science and nanoscale regio-selective surface chemistry.

232 budding, and vesicular topographies through nanoscale reorganization of lipids, proteins, and carboh

233 usceptibility (chi((2))) of materials at the nanoscale represents an ongoing technological challenge

234 ating and handling data for large volumes at nanoscale resolution have thus restricted vertebrate stu

235 ing technique for assembling structures with nanoscale resolution through self-assembly by basic inte

236 rtunity to quantify protein copy number with nanoscale resolution.

237 single cells with individual measurements at nanoscale resolution.

238 e creation of diverse lateral junctions with nanoscale resolution.

239 le large, complex assemblies that can retain nanoscale resolution.

240 etic nanomotors paves the way to intelligent nanoscale robotic systems that are capable of cooperatin

241 Wirelessly controlled nanoscale robots have the potential to be used for both

242 -film polycrystalline Pt, with some apparent nanoscale roughness that was not translated into an incr

243 applications in high resolution imaging with nanoscale scanning electrochemical microscopy (SECM) and

244 In our experiments, we use two nanoscale scatterers to tune a whispering-gallery-mode m

245 hallenging task to quantitatively understand nanoscale SECM images, which requires accurate character

246 oaches - stable isotope probing coupled with nanoscale secondary ion mass spectrometry (nanoSIMS) and

247 We present a combination of Nanoscale Secondary Ion Mass Spectrometry (NanoSIMS) app

248 Here, we used nanoscale secondary ion mass spectrometry (NanoSIMS) ima

249 We describe here nanoscale self-organizing properties of FtsZ assemblies

250 es are addressed by designing a new class of nanoscale sensors dubbed nanopore extended field-effect

251 The thermal fluctuations of membranes and nanoscale shells affect their mechanical characteristics

252 ies as novel materials to be explored on the nanoscale showing optoelectronic properties tunable with

253 Unlike the bulk displacive transition, nanoscale size-confinement enables us to manipulate the

254 ciples for reusable SPR biosensors utilizing nanoscale-specific electrostatic levitation phenomena in

255 eel with a duplex microstructure composed of nanoscale spheroidized cementite (Fe3C) in an ultrafine-

256 ge ferrite grain size of 430 nm, containing nanoscale spheroidized cementite (Fe3C) particles with a

257 Molecular simulations imply that its nanoscale stiffness is 'defect-driven', i.e., dominated

258 Here, using nanoscale strain engineering, we deterministically achie

259 ed LPN powders that were able to re-assemble nanoscale structure when redispersed in water.

260 ipulation and label-free characterization of nanoscale structures open up new possibilities for assem

261 applications of broadband ultraslow waves in nanoscale structures operating below the diffraction lim

262 , which are heterogeneous and highly dynamic nanoscale structures usurped by various viruses.

263 -pot fashion have so far led to much smaller nanoscale structures.

264 Our imaging method enables the nanoscale study of topological magnetic structures in sy

265 e first time the influence of macroscale and nanoscale substrate modulus on whole animal adhesion on

266 the pool boiling performance by introducing nanoscale surface features is an attractive approach in

267 been extensively utilized to explore various nanoscale surface properties.

268 hing phase-change heat transfer processes by nanoscale surface texturing can lead to higher energy tr

269 asures to characterize the hydrophobicity of nanoscale surfaces and caution against the use of additi

270 n has been demonstrated in several important nanoscale systems, including nanocrystal quantum dots, c

271 anofluidics, molecular separation, and other nanoscale technologies.

272 s ability to identify unknown samples at the nanoscale thanks, in first approximation, to the direct

273 Here, we propose an approach suitable to the nanoscale that is based on pseudomagnetic fields.

274 vides new 3D floc geometric data sets at the nanoscale that will be critical in the development of co

275 At the nanoscale, the interaction between the dye dipoles and s

276 ectron tomography is pushed further into the nanoscale, the limitations of rotation stages become mor

277 mbly techniques enable lattice design at the nanoscale; the scaling-up of nanolattice fabrication is

278 We studied the nanoscale thermal expansion of a suspended resistor both

279 nons move and the physical mechanisms behind nanoscale thermal transport, however, remains poorly und

280 between a Au-coated probe featuring embedded nanoscale thermocouples and a heated planar Au substrate

281 ave recently become well understood: (i) the nanoscale thickness ([Formula: see text]300 nm) of nacre

282 top-down techniques to obtain control on the nanoscale (through silk conformational changes), microsc

283 ield (10(5)-10(6) V m(-2)) at the conductive nanoscale tip (4) .

284 derstanding the nature of charge carriers in nanoscale titanium dioxide is important for its use in s

285 interest to transfer mechanical motions from nanoscale to macroscale in order to access new kinds of

286 at the generation of hot electrons makes the nanoscale tunnel junctions highly reactive and facilitat

287 copper samples that contain highly oriented nanoscale twins.

288 olve structure-property relationships at the nanoscale under working conditions, strict data measurem

289 ification of a mechanical actuation from the nanoscale up to a macroscopic response in the bulk mater

290 ilicon layer through hundreds of millions of nanoscale vent holes on each chip by gas-phase Xenon dif

291 symmetry of the dianionic template creates a nanoscale version of the box weave.

292 f these membrane proteins after isolation in nanoscale vesicles derived from specific organelles.

293 Here, we propose a new method to extract nanoscale viscoelastic properties of soft samples like l

294 ons of pH dynamics during endocytosis at the nanoscale, we have specifically designed a family of rat

295 r understanding of chemical processes at the nanoscale, with special interest on in situ catalysts an

296 ee-dimensional magnetic configuration at the nanoscale within micrometre-sized samples.

297 cision measurement of the magnetic fields of nanoscale write heads, which is important for future min

298 Guided by microscale X-ray CT, nanoscale X-ray CT is used to investigate the size and m

299 nd that ATP-dependent activities enhance the nanoscale z fluctuations but stretch out the membrane la

300 This study investigated the efficiency of nanoscale zero-valent iron combined with persulfate (NZV