ライフサイエンスコーパス: electron microscope

1 ividual nanostructures inside a transmission electron microscope.

2 her pressure or temperature is raised in the electron microscope.

3 awley rats were acquired with a transmission electron microscope.

4 0 kV in an aberration-corrected transmission electron microscope.

5 ries takes approximately 12 h on a JEM2200FS electron microscope.

6 using a nanomechanical device in a scanning electron microscope.

7 tals under compression within a transmission electron microscope.

8 ifruits slices was examined using a Scanning Electron Microscope.

9 incident electron beam using a transmission electron microscope.

10 tional spectroscopy to be carried out in the electron microscope.

11 pectroscopy in an environmental transmission electron microscope.

12 izing DNA and DNA-protein complexes using an electron microscope.

13 roelectrode arrays was inspected by scanning electron microscope.

14 avelength-scale resolution in a transmission electron microscope.

15 n using an aberration-corrected transmission electron microscope.

16 R-FTIR spectrometer, goniometer and scanning electron microscope.

17 icroscope to the nanometer resolution of the electron microscope.

18 nterferometer in a conventional transmission electron microscope.

19 e two most powerful imaging instruments: the electron microscope.

20 transparent windows inside the vacuum of the electron microscope.

21 in situ Joule-heating inside a transmission electron microscope.

22 ed in the tilted-beam mode of a transmission electron microscope.

23 also frozen in vitreous ice and imaged in an electron microscope.

24 labeling and observation in the transmission electron microscope.

25 w-dose data using an FEI Tecnai transmission electron microscope.

26 at cryogenic temperature in the transmission electron microscope.

27 les during in situ heating in a transmission electron microscope.

28 scence immunocytochemistry with detection by electron microscope.

29 replica for examination in the transmission electron microscope.

30 labeled boutons in areas TE and V1 using the electron microscope.

31 anoindentation experiments in a transmission electron microscope.

32 s judged by its "golf tee" morphology in the electron microscope.

33 articles followed by imaging with a scanning electron microscope.

34 ies require the additional resolution of the electron microscope.

35 g membrane of 2D materials inside a scanning electron microscope.

36 eometry in an unmodified 200 kV transmission electron microscope.

37 simultaneously combined with imaging in the electron microscope.

38 canning electron microscopy and transmission electron microscope.

39 thodology is easily affordable in any modern electron microscope.

40 loss spectroscopy in a scanning transmission electron microscope.

41 diffraction in an environmental transmission electron microscope.

42 etic field were analysed by the transmission electron microscope.

43 low cytometry, and confocal and transmission electron microscope.

44 etallic glass nanorods inside a transmission electron microscope.

45 ark field imaging in a scanning transmission electron microscope.

46 tional and aberration corrected transmission electron microscopes.

47 roprobes as well as scanning or transmission electron microscopes.

48 generation aberration-corrected transmission electron microscopes allow the vast majority of single a

49 alysts in an aberration-corrected analytical electron microscope allows, for the first time, direct i

50 -exclusion chromatography, and transmittance electron microscope analyses revealed that hydrogen bond

51 Electron microscope analysis of hippocampal tissues in t

52 In scanning electron microscope analysis, diminution in silicone was

53 th the results from immunohistochemistry and electron microscope analysis, the distribution of type I

54 ly exhibit multiple distinct morphologies in electron microscope and atomic force microscope images,

55 tu nanoindentation studies in a transmission electron microscope and corresponding molecular dynamics

56 , 32 TA motoneurons were investigated in the electron microscope and demonstrated a bimodal size dist

57 With a scanning transmission electron microscope and electron energy loss spectroscop

58 ear sulfur anions as confirmed from scanning electron microscope and energy dispersive X-ray spectros

59 Transmission electron microscope and extended X-ray absorption fine s

60 tative in situ compression in a transmission electron microscope and finite-element analysis, we show

61 ivity in layers 2 and 3 of area V1 under the electron microscope and found evidence that GABAergic ne

62 echanical experiments in an in situ scanning electron microscope and show that micrometer-sized Li at

63 ted excitatory synapses in the BLA using the electron microscope and the physical disector design (st

64 Electron microscope and total internal reflection fluore

65 tu electrochemical cell for the transmission electron microscope and use it to track lithium transpor

66 osites were characterized using transmission electron microscope and X-ray diffraction, and their ele

67 Combining transmission electron microscopes and density functional theory calcu

68 By combining advanced electron microscopes and detectors with powerful data an

69 The advent of a new generation of electron microscopes and direct electron detectors has r

70 terized by Atomic force microscopy, Scanning electron microscope, and Raman spectroscopy.

71 e microscopy, and cathodoluminescence in the electron microscope are given detailed attention.

72 State-of-the-art light and electron microscopes are capable of acquiring large imag

73 in situ Kr ion irradiation in a transmission electron microscope at room temperature, that nanoporous

74 training of molybdenum inside a transmission electron microscope at room temperature.

75 Here, we use simulations to show that an electron microscope based on a multi-pass measurement pr

76 tions of molecular tags visible in light and electron microscopes become particularly advantageous in

77 plasmonic behaviour in nanostructures in an electron microscope, but hitherto it has not been possib

78 al cathodoluminescence emitted in a scanning electron microscope by nanoparticles with controllable s

79 While electron microscopes can now provide atomic resolution,

80 patial resolution of a scanning transmission electron microscope combined with electron energy-loss s

81 electrochemical device inside a transmission electron microscope--consisting of a single tin dioxide

82 of the ice thickness from one area of a cryo-electron microscope (cryo-EM) specimen grid to another,

83 e nanobiosensor e.g. field emission scanning electron microscope, cyclic voltammetry and electrochemi

84 Here we have used electron microscope cytochemistry to determine structura

85 High-resolution transmission electron microscope data indicate there are no pure wurt

86 Electron microscope demonstration of PLAP activity showe

87 e depth resolution for scanning transmission electron microscope depth sectioning and present initial

88 u observed experimentally using transmission electron microscope during studies of their electrochemi

89 arge carrier mobility measurements, scanning electron microscope, electron diffraction study, and Ram

90 ark field imaging in a scanning transmission electron microscope, elemental analysis, centrifugal par

91 It is only electron microscope (EM) examination that reveals the tr

92 localization of the alpha5-GABA(A)Rs at the electron microscope (EM) level.

93 ulate pressure-mediated bulk flow through 3D electron microscope (EM) reconstructions of interstitial

94 The electron microscope enables direct visualization of thes

95 mbination of Raman spectroscopy and scanning electron microscope-energy dispersive X-rays that opens

96 A scanning electron microscope equipped with a focused gallium ion

97 We used a transmission electron microscope equipped with an in situ heating sta

98 An electron microscope equipped with Zernike phase-contrast

99 Using an environmental scanning electron microscope (ESEM), we observed rupturing of Ama

100 a attached, inside an environmental scanning electron microscope (ESEM).

101 led observation in an environmental scanning electron microscope (ESEM).

102 he novel environmental scanning transmission electron microscope (ESTEM) with 0.1 nm resolution in sy

103 Electron microscope examination of brainstem, cervical a

104 iscussed in light of the results of scanning electron microscope examination of the soil samples.

105 ction is confirmed by real-time transmission electron microscope experimental observations during uni

106 y diffraction (XRD), field emission scanning electron microscope (FE-SEM) and field emission transmis

107 ic voltammetry (CV), field emission scanning electron microscope (FE-SEM) imaging and energy dispersi

108 ical techniques like field emission scanning electron microscope (FE-SEM) with an energy dispersive X

109 ope (FE-SEM) and field emission transmission electron microscope (FE-TEM) respectively.

110 Field Emission Scanning Electron Microscope (FESEM) figures and fluorescence int

111 ere characterized by field emission scanning electron microscope (FESEM).

112 ctures has previously required the use of an electron microscope for imaging.

113 Using an electron microscope from the Sputnik era, they assembled

114 Thin section observation, scanning electron microscope, grain size analysis, mineral compos

115 crystal silicon cantilever on a transmission electron microscope grid by gallium focused-ion-beam mil

116 rast tomography in the scanning transmission electron microscope has been developed to determine the

117 The resolution capability of the scanning electron microscope has increased immensely in recent ye

118 on energy loss spectroscopy performed in the electron microscope has until now been too poor to allow

119 loss spectroscopy (EELS) in the transmission electron microscope have been investigated to determine

120 nical tests in an environmental transmission electron microscope, here we demonstrate that after expo

121 ow, using ultra-high-resolution transmission electron microscope (HRTEM) images of natural and synthe

122 nned Ag under a high resolution transmission electron microscope (HRTEM) reveals the dynamic processe

123 n beam within a high-resolution transmission electron microscope (HRTEM).

124 scope (SEM) and high-resolution transmission electron microscope (HRTEM).

125 Scanning electron microscope images and serial sections demonstra

126 Ultrahigh-resolution electron microscope images demonstrate that samples disp

127 quantification of intensities in dark-field electron microscope images obtained in the tilted-beam m

128 ach in the context of experimental cryogenic electron microscope images of a large ensemble of nontra

129 ith single particle analysis of transmission electron microscope images of negative-stained material

130 Electron microscope images of the ATPase-DNA-binding dom

131 Scanning electron microscope images of the bacteria confirm that

132 Scanning electron microscope images of thin films deposited from

133 Transmission electron microscope images of thin films from a dilute m

134 ion spectra and high resolution transmission electron microscope images prove the high epitaxial qual

135 The comparison of a pair of electron microscope images recorded at different specime

136 Transmission electron microscope images revealed that the cells are p

137 confocal, transmission electron and scanning electron microscope images show the preferential segrega

138 Scanning electron microscope images showed that DPSCs attached we

139 l data sets and the high-resolution scanning electron microscope images were fused into a combined mu

140 Combining in situ through scanning electron microscope images with molecular simulation, we

141 ril width in negatively stained transmission electron microscope images).

142 nique show excellent agreement with scanning electron microscope images, high spatial resolution at <

143 , high-angle annular dark-field transmission electron microscope images, thanks to the difference of

144 by different groups based on high-resolution electron microscope images.

145 were mapped using elemental display scanning electron microscope images.

146 resolution of approximately 23 A from tilted electron microscope images.

147 The SEM (scanning electron microscope) images showed that the DVB particle

148 f polymeric film systems, using transmission electron microscope imaging (TEM) and nuclear magnetic r

149 We used electron microscope imaging and three-dimensional recons

150 ples together with TUNEL assay, transmission electron microscope imaging and Western blot assay all d

151 horetic sampling and subsequent transmission electron microscope imaging were applied to the in-flame

152 The colony-forming unit counts, scanning electron microscope imaging, and dead:live volume ratio

153 py, lattice-resolution scanning transmission electron microscope imaging, and energy dispersive X-ray

154 gh characterization by scanning transmission electron microscope in high angle annular dark field mod

155 Visualization of viruses by the electron microscope in the late 1930s finally settled th

156 n blotting and immunocytochemistry under the electron microscope indicated that the mutant had neithe

157 We show that using a standard scanning electron microscope, individual nanoantenna gap sizes ca

158 A new generation of electron microscopes is able to explore the microscopic

159 solution and flexibility of the transmission electron microscope, it would open up the study of vibra

160 In the electron microscope, labeled swellings form synapses tha

161 u fracture experiments inside a transmission electron microscope, large-scale atomistic simulations a

162 munoperoxidase and immunogold methods at the electron microscope level to determine whether the subce

163 At the electron microscope level, GABA(B) R2 immunoreactivity w

164 ological features were analyzed at light and electron microscope levels.

165 stereological methods at both the light and electron microscope levels.

166 In the electron microscope, mature Abeta plaques comprising a f

167 e edge in situ using an aberration-corrected electron microscope, measure the cross-section for the p

168 Transmission electron microscope micrographs have confirmed the prese

169 y optical microscope, environmental scanning electron microscope, nano/microindentation, and by tensi

170 we report, by using an in situ transmission electron microscope nanoindentation tool, the direct obs

171 nodansylcadaverine staining and transmission electron microscope observation.

172 We report in situ dynamic transmission electron microscope observations of nanocrystalline nick

173 Growth studies and electron microscope observations suggest that CsiA is ac

174 formed in situ indentation in a transmission electron microscope on Al-TiN multilayers with individua

175 accessible with today's intermediate voltage electron microscopes only small prokaryotic cells or per

176 Under a transmission electron microscope, only the M1 layer of the M(NLS-88R)

177 n aberration-corrected scanning transmission electron microscope optimized for low voltage operation

178 hose morphology we visualized using scanning electron microscope pictures.

179 situ heavy ion irradiation in a transmission electron microscope, pre-introduced nanovoids in nanotwi

180 tended to form double-stranded filaments in electron microscope preparations.

181 be-forming lens in the scanning transmission electron microscope provides not only a significant impr

182 lapse imaging of Xenopus tectal neurons with electron microscope reconstructions of imaged neurons, w

183 At electron microscope resolution, parabrachiothalamic axon

184 rrelates of this plasticity, we examined, at electron microscope resolution, the morphology and the s

185 Scanning electron microscope results also suggest that pulsed wav

186 nalysis of labeled apical dendrites under an electron microscope revealed that MCs and eTCs in fact h

187 Examination under an electron microscope revealed that the C2 DRG terminals c

188 ultilayers in a high-resolution transmission electron microscope revealed the z-AlN to wurzite AlN ph

189 atomic imaging and electrical biasing in an electron microscope, revealing the role of topological d

190 tu nanocompression testing in a transmission electron microscope reveals that the strength of larger

191 The electron microscope's ability to resolve three-dimension

192 Scanning electron microscope (SEM) and Energy Dispersive X-Ray An

193 es of BNNSs are characterized using scanning electron microscope (SEM) and high-resolution transmissi

194 Using the scanning electron microscope (SEM) and micro computed tomography

195 ochlear histology was examined with scanning electron microscope (SEM) and transmission electron micr

196 Scanning electron microscope (SEM) and transmission electron micr

197 d structural characterizations by a scanning electron microscope (SEM) and X-ray diffraction (XRD) co

198 Installed in a scanning electron microscope (SEM) field emission gun, our tip sh

199 To characterize the samples, scanning electron microscope (SEM) images and confocal microscope

200 of particulates were measured from scanning electron microscope (SEM) images of the collected ablate

201 y and higher surface area, based on scanning electron microscope (SEM) images.

202 (CT), plasma focused ion beam (FIB) scanning electron microscope (SEM) imaging and scanning transmiss

203 Evaluation of tissue samples with scanning electron microscope (SEM) imaging showed three-dimension

204 condary electron (SE) signal in the scanning electron microscope (SEM) is a technique gaining impulse

205 Scanning electron microscope (SEM) observations indicated that PM

206 Scanning electron microscope (SEM) revealed that the internal sur

207 The scanning electron microscope (SEM) stereo imaging technique was u

208 tes properties were accomplished by scanning electron microscope (SEM), electrochemical impedance spe

209 atomic force microscope (AFM) or a scanning electron microscope (SEM), optical tweezers, and focused

210 y photoelectron spectroscopy (XPS), scanning electron microscope (SEM), quartz crystal microbalance (

211 hysical form visible on photos taken with an electron microscope (SEM).

212 features are clearly visible with a scanning electron microscope (SEM).

213 g of nanoscience images obtained by scanning electron microscope (SEM).

214 ive X-ray spectrometry (EDX) with a scanning electron microscope (SEM).

215 nuous electron beam of conventional scanning electron microscopes (SEM) limits the temporal resolutio

216 tion distribution were analyzed via scanning electron microscope(SEM) and energy dispersive spectrome

217 vances in the spatial resolution of scanning electron microscopes (SEMs), which are by far the most w

218 while imaging within an in situ transmission electron microscope show that the electric field modifie

219 experiments inside scanning and transmission electron microscopes show that penta-twinned silver nano

220 ace analysis of the product under a scanning electron microscope showed an increasingly rigid density

221 n aberration-corrected scanning transmission electron microscope (STEM) can enable direct correlation

222 e aberration-corrected scanning transmission electron microscope (STEM) has emerged as a key tool for

223 cope (SEM) imaging and scanning transmission electron microscope (STEM) tomography.

224 AADF) imaging within a scanning transmission electron microscope (STEM).

225 rected high-resolution scanning transmission electron microscope (STEM).

226 maged in liquid with a scanning transmission electron microscope (STEM).

227 n aberration-corrected scanning transmission electron microscope (STEM).

228 series acquired in the scanning transmission electron microscope (STEM).

229 units and 70 S ribosomes from X-ray and cryo-electron microscope structures, and the platform is pred

230 Electron microscope studies show that embryos depleted o

231 Transmission electron microscope studies showed clear chemical modula

232 Additionally, scanning electron microscope study indicated morphological damage

233 High-resolution transmission electron microscope (TEM) and scanning TEM analysis show

234 st to observe in a conventional transmission electron microscope (TEM) and too slow for ultrafast ele

235 a SERRS/fluorescence map and a transmission electron microscope (TEM) collage of the same area.

236 measurement capabilities in the transmission electron microscope (TEM) for in situ quantitative tensi

237 actions at the nanoscale in the transmission electron microscope (TEM) has been demonstrated.

238 cles using aberration-corrected transmission electron microscope (TEM) imaging and monochromated scan

239 The transmission electron microscope (TEM) imaging, UV-vis spectrophotome

240 Transmission electron microscope (TEM) observation reveals distinct d

241 Measurements with a transmission electron microscope (TEM) show that nano-Se particles sy

242 g electron microscope (SEM) and transmission electron microscope (TEM) showed cell membrane damage co

243 A systematic transmission electron microscope (TEM) study revealed a similar struc

244 g electron microscopy (SEM) and transmission electron microscope (TEM) techniques were used for phase

245 Here, we describe how to use Transmission Electron Microscope (TEM) to obtain Electron Magnetic Ci

246 g electron microscope (SEM) and transmission electron microscope (TEM), as well as the nuclear labeli

247 Observed with the transmission electron microscope (TEM), CLDIs were bounded by an atyp

248 reeze-substituted sections in a transmission electron microscope (TEM), combined with conventional TE

249 ng electron microscopy (FESEM), transmission electron microscope (TEM), energy dispersive X-ray spect

250 d using an aberration-corrected transmission electron microscope (TEM).

251 ne crystals when observed under Transmission Electron Microscope (TEM).

252 les, have been characterized by transmission-electron-microscope (TEM) image analysis.

253 e been determined using 300-keV transmission electron microscopes (TEMs).

254 In situ scanning electron microscope tests of individual nanowires showed

255 ryo-EM data using an FEI Tecnai transmission electron microscope that can subsequently be processed t

256 Under a transmission electron microscope, the NP-RNA complex appears as a nuc

257 ion of TiN in a high-resolution transmission electron microscope, the nucleation of full as well as p

258 Due to the limited tilt angles in the electron microscope, the tomographic reconstructions are

259 At the sizes visible within transmission electron microscope they appear nearly immobile.

260 images can be obtained on many transmission electron microscopes, this work should facilitate MPL de

261 loss spectroscopy in a scanning transmission electron microscope to around ten millielectronvolts now

262 cture-toughness measurements in the scanning electron microscope to characterize effects at micromete

263 roscopy mapping with a scanning transmission electron microscope to confirm the transition metal cati

264 us to apply the powerful capabilities of the electron microscope to imaging and analysis of liquid sp

265 r diffraction (EBSD) technique in a scanning electron microscope to non-destructively characterise an

266 e in situ heating in a scanning transmission electron microscope to observe the transformation of an

267 d nanofabricated diffraction holograms in an electron microscope to produce multiple electron vortex

268 eynman once asked physicists to build better electron microscopes to be able to watch biology at work

269 ing convergent-beam geometry in an ultrafast electron microscope, to selectively probe propagating tr

270 oscopy analyses, including three-dimensional electron microscope tomographic imaging, have fundamenta

271 orted to be the highest, were analyzed using electron microscope tomography (EMT).

272 sicles in glutamatergic synapses revealed by electron microscope tomography in unstimulated, dissocia

273 Focused ion beam/scanning electron microscope tomography reveals the key membrane

274 Here we used electron microscope tomography to obtain 3D visualizatio

275 Using live-cell imaging and electron microscope tomography, we find that the mitotic

276 intermediate-voltage electron microscopy and electron microscope tomography.

277 ar to active zone structures described using electron microscope tomography.

278 es with a single pulse in the same ultrafast electron microscope (UEM) as used before in the single-e

279 ns suffer radiation damage when imaged in an electron microscope, ultimately limiting the attainable

280 tion, and additional analysis using scanning electron microscope was performed.

281 ompression experiments inside a transmission electron microscope we can directly observe the deformat

282 Via bright-field imaging with an ultrafast electron microscope, we are able to image the sub-picose

283 Using a transmission electron microscope, we detected a 5.7-electron volt (21

284 in situ annealing in a scanning transmission electron microscope, we directly discern five distinct s

285 n aberration-corrected scanning transmission electron microscope, we find that a single point defect

286 y, and probing at higher resolution with the electron microscope, we find that glial development in D

287 Using a scanning electron microscope, we have developed and implemented a

288 By growing III-V nanowires in a transmission electron microscope, we measured the local kinetics in s

289 ron energy-loss spectrum in the transmission electron microscope, we quantified the optical propertie

290 ning in an aberration-corrected transmission electron microscope, we report on the salient atomistic

291 in situ electrical biasing in a transmission electron microscope, we show that electronic band bendin

292 uminium inside an environmental transmission electron microscope, we show that hydrogen exposure of j

293 ion irradiation technique in a transmission electron microscope, we show that nanoporous (NP) Ag has

294 n films under a high-resolution transmission electron microscope, we show that the plasticity mechani

295 Using the electron microscope, we studied spines and their associa

296 an be observed in the environmental scanning electron microscope, which also reveals the presence of

297 r aberration-corrected scanning transmission electron microscope, which provides a factor of 100 incr

298 electron beam of a conventional transmission electron microscope; which can strip away multiple layer

299 n be identified with high probability in the electron microscope without specific labeling.

300 Vibrational spectroscopy in the electron microscope would be transformative in the study