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1 th immobilized DNA was done using a scanning electron microscope.
2 g membrane of 2D materials inside a scanning electron microscope.
3 eometry in an unmodified 200 kV transmission electron microscope.
4 simultaneously combined with imaging in the electron microscope.
5 canning electron microscopy and transmission electron microscope.
6 thodology is easily affordable in any modern electron microscope.
7 loss spectroscopy in a scanning transmission electron microscope.
8 nanostructures in a (scanning) transmission electron microscope.
9 diffraction in an environmental transmission electron microscope.
10 etic field were analysed by the transmission electron microscope.
11 low cytometry, and confocal and transmission electron microscope.
12 etallic glass nanorods inside a transmission electron microscope.
13 ark field imaging in a scanning transmission electron microscope.
14 her pressure or temperature is raised in the electron microscope.
15 spersive spectrometer attached to a scanning electron microscope.
16 awley rats were acquired with a transmission electron microscope.
17 0 kV in an aberration-corrected transmission electron microscope.
18 ries takes approximately 12 h on a JEM2200FS electron microscope.
19 using a nanomechanical device in a scanning electron microscope.
20 ifruits slices was examined using a Scanning Electron Microscope.
21 incident electron beam using a transmission electron microscope.
22 tional spectroscopy to be carried out in the electron microscope.
23 pectroscopy in an environmental transmission electron microscope.
24 izing DNA and DNA-protein complexes using an electron microscope.
25 roelectrode arrays was inspected by scanning electron microscope.
26 avelength-scale resolution in a transmission electron microscope.
27 n using an aberration-corrected transmission electron microscope.
28 R-FTIR spectrometer, goniometer and scanning electron microscope.
29 icroscope to the nanometer resolution of the electron microscope.
30 e two most powerful imaging instruments: the electron microscope.
31 e aberration corrected scanning transmission electron microscope.
32 ectroscopic analysis within the transmission electron microscope.
33 n of isotopically labeled molecules with the electron microscope.
34 myelin in Shiverer mice brain seen under the electron microscope.
35 ividual nanostructures inside a transmission electron microscope.
36 tals under compression within a transmission electron microscope.
37 nterferometer in a conventional transmission electron microscope.
38 at cryogenic temperature in the transmission electron microscope.
39 tional and aberration corrected transmission electron microscopes.
40 roprobes as well as scanning or transmission electron microscopes.
41 generation aberration-corrected transmission electron microscopes allow the vast majority of single a
42 alysts in an aberration-corrected analytical electron microscope allows, for the first time, direct i
43 -exclusion chromatography, and transmittance electron microscope analyses revealed that hydrogen bond
45 ne and atropine in the quids, while scanning electron microscope analysis confirms most to be Datura
48 th the results from immunohistochemistry and electron microscope analysis, the distribution of type I
49 tu nanoindentation studies in a transmission electron microscope and corresponding molecular dynamics
51 ear sulfur anions as confirmed from scanning electron microscope and energy dispersive X-ray spectros
53 echanical experiments in an in situ scanning electron microscope and show that micrometer-sized Li at
55 tu electrochemical cell for the transmission electron microscope and use it to track lithium transpor
56 osites were characterized using transmission electron microscope and X-ray diffraction, and their ele
57 is a technique often implemented on scanning electron microscopes and a regularly used method for qua
65 in situ Kr ion irradiation in a transmission electron microscope at room temperature, that nanoporous
67 Here, we use simulations to show that an electron microscope based on a multi-pass measurement pr
68 rfused small vessels were (mean +/- scanning electron microscope) BD rats (40% +/- 6%), sham-operated
69 plasmonic behaviour in nanostructures in an electron microscope, but hitherto it has not been possib
70 al cathodoluminescence emitted in a scanning electron microscope by nanoparticles with controllable s
72 patial resolution of a scanning transmission electron microscope combined with electron energy-loss s
73 electrochemical device inside a transmission electron microscope--consisting of a single tin dioxide
74 of the ice thickness from one area of a cryo-electron microscope (cryo-EM) specimen grid to another,
75 e nanobiosensor e.g. field emission scanning electron microscope, cyclic voltammetry and electrochemi
77 u observed experimentally using transmission electron microscope during studies of their electrochemi
78 arge carrier mobility measurements, scanning electron microscope, electron diffraction study, and Ram
79 ark field imaging in a scanning transmission electron microscope, elemental analysis, centrifugal par
81 ulate pressure-mediated bulk flow through 3D electron microscope (EM) reconstructions of interstitial
82 mbination of Raman spectroscopy and scanning electron microscope-energy dispersive X-rays that opens
88 he novel environmental scanning transmission electron microscope (ESTEM) with 0.1 nm resolution in sy
89 iscussed in light of the results of scanning electron microscope examination of the soil samples.
90 ction is confirmed by real-time transmission electron microscope experimental observations during uni
91 y diffraction (XRD), field emission scanning electron microscope (FE-SEM) and field emission transmis
92 are observed by both field-emission scanning electron microscope (FE-SEM) and high-resolution transmi
93 ic voltammetry (CV), field emission scanning electron microscope (FE-SEM) imaging and energy dispersi
94 ical techniques like field emission scanning electron microscope (FE-SEM) with an energy dispersive X
95 y diffraction (XRD), field emission scanning electron microscope (FE-SEM), and transmission electron
96 characterized using field emission scanning electron microscope (FE-SEM, SEM-Mapping), scanning tran
100 characterized using field emission scanning electron microscope (FESEM), energy dispersive X-ray spe
101 -FA were approved by field emission scanning electron microscope (FESEM), transmission electron micro
102 ere characterized by Field Emission Scanning Electron Microscope (FESEM), X-ray diffraction (XRD) and
106 crystal silicon cantilever on a transmission electron microscope grid by gallium focused-ion-beam mil
107 oves the excess solution from a transmission electron microscope grid by pressing absorbent filter pa
108 The resolution capability of the scanning electron microscope has increased immensely in recent ye
109 on energy loss spectroscopy performed in the electron microscope has until now been too poor to allow
110 loss spectroscopy (EELS) in the transmission electron microscope have been investigated to determine
111 nical tests in an environmental transmission electron microscope, here we demonstrate that after expo
112 ow, using ultra-high-resolution transmission electron microscope (HRTEM) images of natural and synthe
114 nned Ag under a high resolution transmission electron microscope (HRTEM) reveals the dynamic processe
119 ach in the context of experimental cryogenic electron microscope images of a large ensemble of nontra
120 ith single particle analysis of transmission electron microscope images of negative-stained material
123 ion spectra and high resolution transmission electron microscope images prove the high epitaxial qual
125 he yarn was embedded into knitwear, scanning electron microscope images revealed an intact nanofibrou
129 l data sets and the high-resolution scanning electron microscope images were fused into a combined mu
131 Contaminated areas were assessed by scanning electron microscope images, chemical composition by ener
132 nique show excellent agreement with scanning electron microscope images, high spatial resolution at <
133 , high-angle annular dark-field transmission electron microscope images, thanks to the difference of
137 f polymeric film systems, using transmission electron microscope imaging (TEM) and nuclear magnetic r
140 ples together with TUNEL assay, transmission electron microscope imaging and Western blot assay all d
142 horetic sampling and subsequent transmission electron microscope imaging were applied to the in-flame
143 scopy (EIS) and also field emission scanning electron microscope imaging were used for electrode char
144 The colony-forming unit counts, scanning electron microscope imaging, and dead:live volume ratio
145 py, lattice-resolution scanning transmission electron microscope imaging, and energy dispersive X-ray
147 icroscope with an environmental transmission electron microscope in a novel experimental set-up.
148 gh characterization by scanning transmission electron microscope in high angle annular dark field mod
150 n blotting and immunocytochemistry under the electron microscope indicated that the mutant had neithe
153 n an atomic resolution scanning transmission electron microscope, it is found that stacking faults an
154 solution and flexibility of the transmission electron microscope, it would open up the study of vibra
156 u fracture experiments inside a transmission electron microscope, large-scale atomistic simulations a
158 e edge in situ using an aberration-corrected electron microscope, measure the cross-section for the p
159 We demonstrate, using in situ transmission electron microscope mechanical testing, that [Formula: s
162 y optical microscope, environmental scanning electron microscope, nano/microindentation, and by tensi
163 we report, by using an in situ transmission electron microscope nanoindentation tool, the direct obs
165 formed in situ indentation in a transmission electron microscope on Al-TiN multilayers with individua
166 accessible with today's intermediate voltage electron microscopes only small prokaryotic cells or per
168 ssing less than 100 kDa using a transmission electron microscope operating at 200 keV coupled with a
169 n aberration-corrected scanning transmission electron microscope optimized for low voltage operation
170 light microscope setup called the Photon Ion Electron microscope (PIE-scope) that enables direct and
171 situ heavy ion irradiation in a transmission electron microscope, pre-introduced nanovoids in nanotwi
173 lapse imaging of Xenopus tectal neurons with electron microscope reconstructions of imaged neurons, w
176 nalysis of labeled apical dendrites under an electron microscope revealed that MCs and eTCs in fact h
177 ultilayers in a high-resolution transmission electron microscope revealed the z-AlN to wurzite AlN ph
178 atomic imaging and electrical biasing in an electron microscope, revealing the role of topological d
179 tu nanocompression testing in a transmission electron microscope reveals that the strength of larger
181 ssed sensing algorithms are used to decrease electron microscope scan time and electron beam exposure
182 membranes for 48 hours followed by scanning electron microscope (SEM) analysis immediately or after
184 es of BNNSs are characterized using scanning electron microscope (SEM) and high-resolution transmissi
186 ochlear histology was examined with scanning electron microscope (SEM) and transmission electron micr
188 d structural characterizations by a scanning electron microscope (SEM) and X-ray diffraction (XRD) co
193 We use a theoretical model based on scanning electron microscope (SEM) images of our substrates to ex
194 (CT), plasma focused ion beam (FIB) scanning electron microscope (SEM) imaging and scanning transmiss
195 Evaluation of tissue samples with scanning electron microscope (SEM) imaging showed three-dimension
197 condary electron (SE) signal in the scanning electron microscope (SEM) is a technique gaining impulse
201 tes properties were accomplished by scanning electron microscope (SEM), electrochemical impedance spe
203 atomic force microscope (AFM) or a scanning electron microscope (SEM), optical tweezers, and focused
204 y photoelectron spectroscopy (XPS), scanning electron microscope (SEM), quartz crystal microbalance (
206 us characterization methods such as scanning electron microscope (SEM), transmission electron microsc
211 nuous electron beam of conventional scanning electron microscopes (SEM) limits the temporal resolutio
212 tion distribution were analyzed via scanning electron microscope(SEM) and energy dispersive spectrome
213 pression experiments conducted in a scanning electron microscope show an emergent electromechanical r
214 while imaging within an in situ transmission electron microscope show that the electric field modifie
215 experiments inside scanning and transmission electron microscopes show that penta-twinned silver nano
216 ace analysis of the product under a scanning electron microscope showed an increasingly rigid density
218 n aberration-corrected scanning transmission electron microscope (STEM) can enable direct correlation
219 e aberration-corrected scanning transmission electron microscope (STEM) has emerged as a key tool for
223 cal tests conducted in scanning/transmission electron microscopes (STEM/TEM) provide a critical tool
229 st to observe in a conventional transmission electron microscope (TEM) and too slow for ultrafast ele
232 cles using aberration-corrected transmission electron microscope (TEM) imaging and monochromated scan
236 g electron microscope (SEM) and transmission electron microscope (TEM) showed cell membrane damage co
238 g electron microscopy (SEM) and transmission electron microscope (TEM) techniques were used for phase
239 Here, we describe how to use Transmission Electron Microscope (TEM) to obtain Electron Magnetic Ci
241 g electron microscope (SEM) and transmission electron microscope (TEM), as well as the nuclear labeli
243 reeze-substituted sections in a transmission electron microscope (TEM), combined with conventional TE
244 ng electron microscopy (FESEM), transmission electron microscope (TEM), energy dispersive X-ray spect
245 croscopy (AFM), High-resolution transmission electron microscope (TEM), Fourier-transform infrared sp
246 ning electron microscope (SEM), transmission electron microscope (TEM), x-ray diffraction (XRD) metho
247 ning electron microscope (SEM), transmission electron microscope (TEM), x-ray diffraction (XRD), cycl
252 canning electron microscope and transmission electron microscope testing of the smooth and rough nano
254 ically studied using analytical transmission electron microscope that together with outcomes from adv
255 parallel imaging pipeline using transmission electron microscopes that scales this technology, implem
256 ion of TiN in a high-resolution transmission electron microscope, the nucleation of full as well as p
259 loss spectroscopy in a scanning transmission electron microscope to around ten millielectronvolts now
261 cture-toughness measurements in the scanning electron microscope to characterize effects at micromete
262 roscopy mapping with a scanning transmission electron microscope to confirm the transition metal cati
263 loss spectroscopy in a scanning transmission electron microscope to directly resolve carbon-site-spec
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
269 eynman once asked physicists to build better electron microscopes to be able to watch biology at work
270 ing convergent-beam geometry in an ultrafast electron microscope, to selectively probe propagating tr
271 oscopy analyses, including three-dimensional electron microscope tomographic imaging, have fundamenta
272 show by electron tomography [3D transmission electron microscope tomography (3D TEM)] that chirality
274 sicles in glutamatergic synapses revealed by electron microscope tomography in unstimulated, dissocia
281 ns suffer radiation damage when imaged in an electron microscope, ultimately limiting the attainable
284 Via bright-field imaging with an ultrafast electron microscope, we are able to image the sub-picose
285 in situ annealing in a scanning transmission electron microscope, we directly discern five distinct s
286 n aberration-corrected scanning transmission electron microscope, we find that a single point defect
288 By growing III-V nanowires in a transmission electron microscope, we measured the local kinetics in s
289 ning in an aberration-corrected transmission electron microscope, we report on the salient atomistic
290 y using an aberration-corrected transmission electron microscope, we report the fabrication of precio
291 ion electron energy-loss spectroscopy in the electron microscope, we show that a single substitutiona
292 in situ electrical biasing in a transmission electron microscope, we show that electronic band bendin
293 uminium inside an environmental transmission electron microscope, we show that hydrogen exposure of j
294 ion irradiation technique in a transmission electron microscope, we show that nanoporous (NP) Ag has
295 n films under a high-resolution transmission electron microscope, we show that the plasticity mechani
297 electron beam of a conventional transmission electron microscope; which can strip away multiple layer
298 e promise of vibrational spectroscopy in the electron microscope with single-atom sensitivity and has