ライフサイエンスコーパス: nanoscale

1 Particles ranged in size from micro- to nanoscale.

2 tions in which this region is bounded at the nanoscale.

3 ve biological systems from the micro- to the nanoscale.

4 e of their ability to probe materials at the nanoscale.

5 standing of the self-assembly process at the nanoscale.

6 possible, and may contribute to toxicity at nanoscale.

7 nsiderable inner electric field force at the nanoscale.

8 erial platform for manipulating light at the nanoscale.

9 nderstanding for correlating diseases at the nanoscale.

10 to investigate and manipulate systems on the nanoscale.

11 plasma frequencies for metals probed at the nanoscale.

12 rrow-bandgap semiconductor to a metal at the nanoscale.

13 rm for controlling the flow of energy at the nanoscale.

14 ngth and high electrical conductivity at the nanoscale.

15 gy to visualize cellular architecture at the nanoscale.

16 incoherent charge transport processes at the nanoscale.

17 aghemite due to the Kirkendall effect at the nanoscale.

18 ge effects in intracellular diffusion at the nanoscale.

19 y for active control of heat currents at the nanoscale.

20 vation through a mechanism unexplored on the nanoscale.

21 probe correlated electronic phenomena at the nanoscale.

22 the folding of individual chromosomes at the nanoscale.

23 ns to investigate diffusion phenomena at the nanoscale.

24 ful means of retrieving information from the nanoscale.

25 hannels of the 2D material are suspended and nanoscaled.

26 ropelled micromotors, which allow responsive nanoscale actuation and delivery.

27 irreversible phase transition, forming solid nanoscale aggregates associated with neurodegenerative d

28 ough bulk (selective extractions, EXAFS) and nanoscale analysis (correlative SEM and nanoSIMS) that o

29 s hold great promise for imaging function in nanoscale and biological systems with atomic resolution.

30 sight into control of fascin dynamics at the nanoscale and into the mechanisms governing rapid cytosk

31 as an important parameter that distinguishes nanoscale and macroscale carrier behaviors.

32 inhomogeneous compositions and properties at nanoscale and small adjustable band gap ranges.

33 en in-situ supervised learning systems using nanoscale and stochastic analog memory synapses.

34 directly and quantitatively assess smaller (nanoscale and submicron) liquid domains have been limite

35 es and shows that both electrostatic (at the nanoscale) and thermal (in bulk) stimuli can be used to

36 nd nucleus is spatially heterogeneous at the nanoscale, and that variations in local diffusivity corr

37 The micro or nanoscale architectures of these structures significantl

38 protecting groups and with precisely defined nanoscale architectures.

39 k, which will require detailed insights into nanoscale assembly mechanisms during spinning, as well a

40 First, by visualizing nanoscale BCR clusters, we provide direct evidence that

41 This nanoscale bimodal imaging approach can be also used to i

42 emperature particle ex-solution on important nanoscale binary oxides.

43 urface plasmon resonance peak can generate a nanoscale bubble, which can encapsulate the NP (i.e., su

44 As nanoscale building blocks, proteins offer unique advanta

45 lectric properties of other materials on the nanoscale by using electrostatic scanning probe techniqu

46 ) and Pb(3)S(2)Cl(2)) can be prepared on the nanoscale by wet-chemical approaches.

47 ediment owing to the importance of achieving nanoscale (ca. 100 nm) dimensions, as opposed to microsc

48 atial confinement of Fenton chemistry at the nanoscale can significantly enhance the kinetics of radi

49 On-chip/on-petri dish nanoscale capacitance calibration standards are used to

50 The DNC can host nanoscale cargoes, which allows for the integration with

51 Nanoscale catalysts that can enable Fenton-like chemistr

52 ions that will enable profound insights into nanoscale catalytic mechanisms.

53 sufficient to yield 'nanolympiadane'(10), a nanoscale catenane composed of five interlocked toroids.

54 investigated the pressure requirement for a nanoscale cavitation to grow in water and gel.

55 ter-size and sub-micrometer metal particles, nanoscale ceramic particles, clays, polymers, hybrid mat

56 However, a critical nanoscale characterization gap has emerged between the b

57 Nanoscale charge accumulations were observed in MAPbBr(3

58 ution of scanning probe microscopy, allowing nanoscale chemical analysis of almost any organic materi

59 rcumvents the Abbe diffraction limit, allows nanoscale chemical characterization of surfaces.

60 brought SICM to the forefront as a tool for nanoscale chemical measurement for a wide range of appli

61 The nanoscale co-organization of neurotransmitter receptors

62 Superresolution microscopy revealed distinct nanoscale colocalization of LEL-expressing TRPML1 channe

63 gle-molecule electret is a long-sought-after nanoscale component because it can lead to miniaturized

64 lo simulations, which bridge the gap between nanoscale computational insights and macroscale experime

65 obility along vertical direction revealed by nanoscale conductive scanning force microscopy and macro

66 bit a hyperbolic dispersion and propagate as nanoscale-confined volume modes in thin flakes.

67 Here, we show that a plasmonic nanoscale construct serving as an 'add-on' label for a b

68 on properties make DNA a useful material for nanoscale construction, but degradation in biological fl

69 a flow-through reactive gas cell to achieve nanoscale control of defects in monolayer MoS(2).

70 ort to realize the prospect of higher-order, nanoscale control over associative cross-link exchange a

71 t uniquely difficult challenges to effective nanoscale crystalline characterization.

72 ing and correlative spectroscopies, that the nanoscale crystallites of hydroxylapatite (Ca(5)(PO(4))(

73 60%, respectively; the foliar application of nanoscale Cu reversed this damage.

74 fence- and health-related genes correlates a nanoscale Cu-enhanced innate disease response to reduced

75 As a result, nanoscale curvature provides a new degree of freedom to

76 l properties with great potential for future nanoscale device applications.

77 of PPNs and SRNs in hardware using emerging nanoscale devices can greatly improve the efficiency of

78 playing a crucial role in the development of nanoscale devices for the realization of spin qubits, Ma

79 complicates their integration in multi-spin nanoscale devices, because the field cannot be localized

80 n of networks with characteristics combining nanoscale diameters of one-dimensional carbon nanotube a

81 scovery of ultralarge elastic deformation in nanoscale diamond and machine learning of its electronic

82 oach thus unveils and differentiates between nanoscale diffusional heterogeneities of different origi

83 ctromagnetic interference (EMI) shielding of nanoscale dimension.

84 structure, shape of water-filled pores, and nanoscale dimensions of membranes with different lipid c

85 ar surface amenable to functionalization and nanoscale dimensions that confer photoluminescence.

86 localized to and/or induce the formation of nanoscale domain boundaries of locally ordered dipoles.

87 en to construct multiphase boundaries, where nanoscale domains with local structural and polar hetero

88 oparticle (NP) entries as core components of nanoscale drug delivery systems (NDDSs) by making use of

89 MOFs) are emerging as leading candidates for nanoscale drug delivery, as a consequence of their high

90 l regulation of NRas in melanoma through its nanoscale dynamic organization and a new mechanism for M

91 Nanoscale dynamic organization of WT and mutant NRas rel

92 Direct quantitative measurements of nanoscale dynamical processes associated with structural

93 However, the nanoscale dynamics of tissue-specific immune cells have

94 Herein, we demonstrate nanoscale electrochemical imaging of hydrogen evolution

95 means not only for advancing the fundamental nanoscale electrokinetic study as well as interfacial io

96 However, implementation of SiGe in nanoscale electronic devices necessitates suppression of

97 s have generated exciting implications about nanoscale energy flow, molecular chemotaxis, and self-po

98 tioning two-qubit quantum register using the nanoscale ensemble of arsenic quadrupolar nuclear spins

99 coherence is limited by interaction with the nanoscale ensemble of atomic nuclear spins, which is par

100 at the same level as other materials on the nanoscale, even though YAG:Ce microcrystalline materials

101 ulate this entity with electric field on the nanoscale expand the existing phenomenology of functiona

102 These influences have become clearest in nanoscale experiments, in terms of strength, hardness an

103 lpha-MoO(3) is reported without the need for nanoscale fabrication on the alpha-MoO(3).

104 or synthesizing them with control over their nanoscale features (e.g., particle compositions, sizes,

105 roscopy and computational modeling to define nanoscale features of Na(v)1.5 localization and distribu

106 These chips have nanoscale features that dissipate power resulting in nan

107 es of structures and features, i.e. flexible nanoscale fibers, nanoparticles/clusters, and a low-pres

108 In this study we used nanoscale flow cytometry in conjunction with an engineer

109 We show that Ge-SiC resonators with nanoscale footprint can support sheet and edge surface m

110 able to other heterogeneous materials at the nanoscale for correlative multimodal characterizations.

111 ble amount of the particulates occurred as a nanoscale fraction that sometimes passed through the POU

112 the formation of a single-molecule wire in a nanoscale gap.

113 Here, we conduct nanoscale geochemical analysis of a framboidal magnetite

114 of Janus glycodendrimers, self-organize into nanoscale glycodendrimersomes.

115 The presence of nanoscale grooves greatly enhances the outgrowth of neur

116 ication of aligned microfibers engraved with nanoscale grooves to promote neurite outgrowth and cell

117 erojunctions from conjugated polymers on the nanoscale has attracted recent attention as a consequenc

118 o understand the chemical composition at the nanoscale, has stimulated the convergence of IR and Rama

119 e fit parameters: (i) fractional coverage by nanoscale heterogeneity; (ii) efficiency of return to th

120 A nanoscale hierarchical dual-phase structure is reported

121 nning filaments from nanocellulose, Nature's nanoscale high-performance building block, which will re

122 e features that dissipate power resulting in nanoscale hotspots leading to device failures.

123 In this work, we combined nanoscale imaging (nano secondary ion mass spectrometry

124 Previous nanoscale imaging by atomic force microscopy (AFM) showe

125 d exhibited the highest particle counts, yet nanoscale imaging revealed the additional presence of ag

126 Nanoscale imine-linked covalent organic frameworks (nCOF

127 engineering from the macroscale down to the nanoscale, imparting wood-based materials with multiple

128 Understanding nanoscale interactions at the interface between two medi

129 inuum-scale rate coefficients were linked to nanoscale interactions via mechanistic pore-scale colloi

130 Here, we demonstrate a nanoscale interface-engineering approach that harnesses

131 Despite strong empirical correlation, the nanoscale interplay between excitons and local crystalli

132 ults from native mass spectrometry (MS) with nanoscale ion emitters indicate that netropsin can simul

133 Controlling the self-assembled nanoscale ionic aggregates in single-ion conducting poly

134 Directed motion at the nanoscale is a central attribute of life, and chemically

135 tial organization of functional sites at the nanoscale is a critical challenge in bifunctional cataly

136 Modifying material properties at the nanoscale is crucially important for devices in nano-ele

137 e possibility of structuring material at the nanoscale is essential to control light-matter interacti

138 Control of thermal transport at the nanoscale is of great current interest for creating nove

139 memristive switching of tunneling current in nanoscale junctions of ultrathin CrI(3) , a natural laye

140 stabilized uniform extreme tensile strain in nanoscale La(0.7)Ca(0.3)MnO(3) membranes, exceeding 8% u

141 an plasma membranes, cryo-EM reveals similar nanoscale lateral heterogeneities.

142 es were significantly reduced from micron to nanoscale level.

143 e rational design of electrocatalysts at the nanoscale level.

144 ric mechanics having hard inorganic matrix), nanoscale-level conductivity, and outstanding performanc

145 se and complex organisation at molecular and nanoscale levels.

146 eminiscent of stress granule substructure or nanoscale liquid droplets.

147 ts for ligand coating while maintaining both nanoscale (local) and macroscale (total) ligand density

148 ic dust particles of inhalable (<10 mum) and nanoscale (<200 nm) size ranges with these particles sma

149 xtract showed average particle diameter on a nanoscale (<200 nm), high homogeneity and stability, hig

150 graded plastic) and the design of artificial nanoscale machines(15).

151 mor microenvironment due to the mechanism of nanoscale macromolecular cooperativity.

152 Nanoscale magnetic imaging is performed using quantum sp

153 of STT-MRAM is that its core component, the nanoscale magnetic tunneling junction (MTJ), is thought

154 fers for, for example, quantum technologies, nanoscale magnetometry, and biosensing.

155 a super-resolution strategy that enables the nanoscale mapping of intracellular diffusivity through l

156 For example, the mechanisms by which i) nanoscale materials can improve targeting and infiltrati

157 e-dependent characteristics that distinguish nanoscale materials from bulk solids arise from constrai

158 g the electronic dynamics of a wide range of nanoscale materials with ultimate spatiotemporal resolut

159 ly transform large aggregated particles into nanoscale materials.

160 can serve a combined testbed to investigate nanoscale mechanics of the living cell membrane.

161 In this work, the nanoscale mechanism for defect suppression at the SiGe-o

162 D has been extensively used to elucidate the nanoscale membrane structure and dynamics via imaging or

163 cisely strain-engineered, substrate-released nanoscale membranes is demonstrated via an epitaxial lif

164 Now, a cationic nanoscale metal-organic framework, W-TBP, is used to fac

165 report the design of a bacteriochlorin-based nanoscale metal-organic framework, Zr-TBB, for highly ef

166 Nanoscale metal-organic frameworks (nMOFs) are excellent

167 Micro- and nanoscale metallic glasses offer exciting opportunities

168 monic nanocavity, which may be useful in the nanoscale metrology of various molecular systems.

169 synchrotron spectromicroscopy to observe the nanoscale mineralogy of fresh, forming skeletons from si

170 ered versus ambient, incidental iron-bearing nanoscale minerals.

171 apability of CL AFM-IR in routine mapping of nanoscale molecular information.

172 etworks, hold a significant place in ordered nanoscale morphologies for their potential applications

173 se observations suggest that with particular nanoscale morphologies the bulk heterojunction can go be

174 n directing the supramolecular structure and nanoscale morphology remains elusive.

175 imaging revealed striking differences in sEV nanoscale morphology, surface nano-roughness, and relati

176 demonstrate that all these key properties of nanoscale MTJs relevant to STT-MRAM applications are rob

177 sport and optical conductivity properties of nanoscaled multilayered films composed of disordered met

178 experimental and computational study of the nanoscale-nanosecond motion of water at the surface of a

179 noclusters, and further in stabilizing these nanoscale Ni catalysts against poisoning by interactions

180 ystal cavities have been explored for stable nanoscale object trapping(4-13).

181 At the trapping locations, the nanoscale objects experience both negligible phototherma

182 Label-free optical imaging of nanoscale objects faces fundamental challenges.

183 Directed high-speed motion of nanoscale objects in fluids can have a wide range of app

184 Engineering the assembly of nanoscale objects into complex and prescribed structures

185 Why can we not see nanoscale objects under a light microscope?

186 vide enough trapping potential depth to trap nanoscale objects.

187 These real-time nanoscale observations will be helpful in engineering be

188 We reveal the co-localization at the nanoscale of zinc and tubulin in dendrites with a molecu

189 Here we use a nanoscale on-tip scanning superconducting quantum interf

190 a fundamental step toward the realization of nanoscale optically inspired devices based on spin waves

191 nstraint that limits the performance of many nanoscale optoelectronic and optomechanical devices incl

192 owever, it has proven challenging to operate nanoscale optomechanical devices at these ultralow tempe

193 f chemical processes that can be probed with nanoscale or even single-molecule resolution.

194 r at very low loadings with a high degree of nanoscale order.

195 Interestingly, this nanoscale organization is highly heterogeneous.

196 The nanoscale organization of active synapses opens new insi

197 The nanoscale organization of biological membranes into stru

198 We report significant changes in the nanoscale organization of GluN2B-NMDARs between proximal

199 The nanoscale organization of key effector molecules has bee

200 e known to be different, the composition and nanoscale organization of key synaptic proteins at these

201 ntity of each glutamate receptor type, their nanoscale organization, and their respective activation.

202 However, much is unknown about the nanoscale origins of the observed magnetic properties of

203 ersatile and powerful imaging methods of the nanoscale over the past two decades.

204 stematically interrogate the impact of these nanoscale parameters on B-cell activation in vitro.

205 se site organization, was crucial for proper nanoscale patterning of the BRP scaffold and needed for

206 We envision these structures as versatile nanoscale pegboards for applications requiring complex 3

207 h chi-low N" diblock copolymers that undergo nanoscale phase separation in the solid state to produce

208 a perspective on various bulk, interface and nanoscale phenomena that require urgent attention within

209 We demonstrate a nanoscale platform that targets and delivers nanomateria

210 high doses of gamma and neutron radiation on nanoscale pMTJs used in STT-MRAM.

211 l as analyte molecules translocate through a nanoscale pore.

212 The incorporation of nanoscale pores into a sheet of graphene allows it to sw

213 and charges, within the one-dimensional (1D) nanoscale pores of surfactant-templated mesoporous silic

214 induce unique membrane "rippling" along with nanoscale pores on A549 cells.

215 Ion channel proteins form water-filled nanoscale pores within lipid bilayers, and their propert

216 d to a number of very fine, Zn/Ca-containing nanoscale precipitates, along with ultra-fine grains.

217 Moreover, the Ag-rich nanoscale precipitates, discordant Ag atoms, and Pb/Sr,

218 ximately 100-micrometre-thick layers down to nanoscale precipitates.

219 For example, nanoscale precise imaging by rapid beam oscillation (nSP

220 Many developed micro/nanoscale propulsion mechanisms are based on the assumpt

221 The nanoscale protein architecture of the kinetochore plays

222 sing ultrastructure expansion microscopy for nanoscale protein mapping, we reveal that POC16 and its

223 trolled growth of metallic nanoparticles, at nanoscale proximity, within a perovskite oxide lattice a

224 he observed differences between extended and nanoscale Pt surfaces, and we highlight the needs in adv

225 Accurate, nanoscale quantification of macrophage morphology reveal

226 scaling up synthesis possible via arrays of nanoscale reaction centres, for example using nanopore m

227 ters can typically be synthesized within the nanoscale regime for a specific composition, isolating c

228 f Munc13, which allow SVs to dock in defined nanoscale relation to Ca2+ channels.

229 rstanding of fossilization mechanisms at the nanoscale remains extremely challenging despite its fund

230 e intracellular physiological processes with nanoscale resolution for an extended period of time.

231 d standard for connectivity analysis because nanoscale resolution is necessary to unambiguously resol

232 diffraction imaging technique that provides nanoscale resolution on extended field-of-view.

233 molecules mum(-2) ) of single molecules with nanoscale resolution remains elusive.

234 ethod with unique geometric capabilities and nanoscale resolution, and micromolding with favorable ma

235 a three-dimensional magnetic microdisc with nanoscale resolution, and with a synchrotron-limited tem

236 lipid-dye interactions with single-molecule, nanoscale resolution.

237 New advances in nanoscale-resolution 3D-printing offer opportunities to

238 ucted from image datasets acquired via e.g., nanoscale-resolution focused ion beam-scanning electron

239 ists of 4,096 platinum-black electrodes with nanoscale roughness fabricated on top of a silicon chip

240 Using (13)C-glucose tracing with correlated nanoscale secondary ion mass spectrometry (NanoSIMS) and

241 Using nanoscale secondary ion mass spectrometry (NanoSIMS), we

242 Nanoscale secondary ion mass spectrometry combined with

243 ose obtained on the same enriched pellets by nanoscale secondary ionization mass spectrometry (NanoSI

244 Colloidal quantum dots (QDs) are nanoscale semiconductor crystals with surface ligands th

245 -fidelity control over multiple defects with nanoscale separations, with strong spin-spin interaction

246 he phonon lifetime of a microwave-frequency, nanoscale silicon acoustic cavity incorporating a phonon

247 After i.v. injection of CLM, its nanoscale size and stimuli-responsiveness facilitated de

248 However, due to the nanoscale size of moire domains, the effects of atomic r

249 Precise creation of a single nanoscale skyrmion is a prerequisite to further understa

250 ptical-field-driven photocurrents in various nanoscale solid-state materials, little has been done in

251 urface vacancies that results from heating a nanoscale solid.

252 erm-selective ion transportation through the nanoscale space using an ionic plasma generation.

253 This method combines nanoscale spatial resolution chemical imaging using the

254 l provides local cyclic voltammograms with a nanoscale spatial resolution for visualizing HER active

255 g(5) different sorts of knots in a synthetic nanoscale strand are lacking.

256 Quantifying key nanoscale structural characteristics of sEVs, collective

257 Perm-selective ion transportation in a nanoscale structure such as nanochannel, nanoporous memb

258 Through careful design of their nanoscale structure, these systems act as biological met

259 cause DNA origami enables precise testing of nanoscale structure-function relationships, we were able

260 These acoustically engineered nanoscale structures provide a window into the material

261 on, we start with the activity of ORR on the nanoscale surface and then focus on the approaches to op

262 ines, for the first time, recent advances in nanoscale surface chemistry, surface science, DFT, adsor

263 sical mechanism of hot-carrier generation in nanoscale systems with strong confinement.

264 understandings cannot always translate into nanoscale systems.

265 y biophysical problems involve molecular and nanoscale targets moving next to a curvilinear track, e.

266 conventional planar surface with microscale/nanoscale textures.

267 ant nanoantenna to couple the IR energy to a nanoscale thermocouple.

268 bryo, which is precisely measured by in vivo nanoscale thermometry using quantum defects in nanodiamo

269 ing a combination of local laser heating and nanoscale thermometry.

270 t utilize the properties of materials at the nanoscale to address extensive and inefficient resource

271 , to precisely map thermal contours from the nanoscale to the microscale.

272 azobenzene-based photoswitches are promising nanoscale tools for neuronal photostimulation.

273 h the DNA points accumulation for imaging in nanoscale topography (DNA-PAINT) technique to map picone

274 ion method, DNA-based points accumulation in nanoscale topography (DNA-PAINT), and the specificity of

275 live-cell points accumulation for imaging in nanoscale topography (PAINT) method that exploits aptame

276 t tension points accumulation for imaging in nanoscale topography (tPAINT), integrating molecular ten

277 ing in rat hippocampal neurons to unveil the nanoscale topography of native GluN2A- and GluN2B-NMDA r

278 Atomic force microscopy on the resulting nanoscale toroids revealed a high percentage of catenati

279 botronics and may have great applications in nanoscale transistor, micro/nano-electronic circuit and

280 uminescence efficiency, we observe discrete, nanoscale trap clusters.

281 , we reveal the existence of a novel defect, nanoscale triangle-shaped vacancy plates.

282 This work has realized the nanoscale triboelectric modulation on electronics, which

283 rinciple was analyzed at first, in which the nanoscale triboelectrification can tune the carrier tran

284 Moreover, the manipulated nanoscale triboelectrification serving as a rewritable f

285 Then with the manipulated nanoscale triboelectrification, the effects of contact f

286 Here, a nanoscale triboelectrification-gated transistor has been

287 individual atoms to design materials at the nanoscale using a proposed method coined "Nano-Topology

288 We quantify distributions on the nanoscale using image statistics and show that the type

289 perspective on the global trends in emerging nanoscale vaccines for infectious diseases and describes

290 We show that direct, label-free nanoscale visualization of neuromelanin and associated m

291 imaging, enhanced spontaneous emission, and nanoscale waveguiding.

292 ves represent a promising route due to their nanoscale wavelength in the gigahertz frequency range an

293 Previous nanoscale weaves(2-16) include isotropic crystalline cov

294 vation of anisotropic strain dynamics at the nanoscale, where identically crystallographically-orient

295 ic skyrmions are topological solitons with a nanoscale winding spin texture that hold promise for spi

296 re many materials have been developed on the nanoscale with excellent optical properties (e.g., semic

297 o mechanically switch the electronics in the nanoscale with fast response (<4 ms) and high resolution

298 The unique nanoscale X-ray computed tomography verifies the well-di

299 The application of nanoscale zerovalent iron (nano-ZVI) particles for groun

300 The reactivity of sulfidized nanoscale zerovalent iron (SNZVI) is affected by the amo