ライフサイエンスコーパス: atomic

1 in nuts by high-resolution continuum source atomic absorption spectrometry after extraction induced

2 tuffs prior to their determinations by flame atomic absorption spectrometry.

3 at trace levels by slotted quartz tube flame atomic absorption spectrophotometry (SQT-FAAS) after pre

4 entional methods such as colorimetric, flame atomic absorption spectroscopy (FAAS), and inductively c

5 r tailoring their catalytic performance with atomic accuracy.

6 s, we describe a linear relationship between atomic and formulaic N-compositions from a range of DOM

7 discharge (LS-APGD) microplasma for combined atomic and molecular (CAM) analysis.

8 ce of the Coulomb coupled motion between the atomic and molecular ions enables subsequent entangling

9 nts that can probe structural changes at the atomic and molecular levels in real time.

10 elop a technology to design materials on the atomic and molecular scales.

11 on took advantage of the data fusion between atomic and molecular spectra in order to characterize th

12 etical studies of ICD processes in different atomic and molecular systems is reviewed.

13 In this study, the intra-atomic (antibonding) and bonding contributions to the to

14 Such images reveal a highly ordered atomic arrangement of sharp grain boundaries and coheren

15 d extensively and are widely used, yet their atomic arrangement remains an open issue.

16 er spectroscopy measurements on bunched fast atomic beams in a collinear geometry.

17 The atomic buckling in 2D "Xenes" (such as silicene) fosters

18 acroscopic scales, whereas the molecular and atomic building blocks behave like rigid particles.

19 ed and a system is created where the TaSe(4) atomic chains are in amorphous state without breaking th

20 that consecutive defect formation, driven by atomic charge compensation, establishes the formation of

21 slower than expected for the predicted high atomic charge states due to significant impact of ion ca

22 State-of-the-art atomic clocks are based on the precise detection of the

23 Microwave atomic clocks have traditionally served as the 'gold sta

24 applications such as neuromorphic computing, atomic clocks, thermometry, and sensing.

25 on loss, and have led to advances in compact atomic clocks, ultrafast ranging, and spectroscopy.

26 n, site-resolved readout and preservation of atomic coherence.

27 trast mechanism detects both light and heavy atomic columns and is robust with respect to specimen th

28 Atomic columns appear as sharp peaks that can be signifi

29 FeMo-cofactor, but the precise structure and atomic composition of FeMoco in its activated form is no

30 This technique allows insight into the atomic composition of van der Waals interactions, offeri

31 F) together with the combined feature set of atomic composition, physicochemical-2grams and two diffe

32 a, the calculated energy, and C, H, O, and N atomic constants given in the tables.

33 polynomials or sums of environment-dependent atomic contributions, which have recently emerged as pow

34 The more precisely atomic coordinates are determined, the more chemical inf

35 a step toward realizing strongly interacting atomic defect ensembles with applications to quantum inf

36 aring their local environments using general atomic descriptors, and also by demonstrating that a mac

37 produce crystals that provided unprecedented atomic detail.

38 ctures of RNA molecules but does not resolve atomic details.

39 nergies significantly smaller than those for atomic diffusion in the liquid.

40 Achieving atomic dispersion requires an artificial increase of the

41 The atomic displacements associated with the freezing of met

42 ygen octahedral rotation forms a fundamental atomic distortion in perovskite oxides, but only a few p

43 ther effective strategy to increase both the atomic efficiency and the chance of tailoring the proper

44 through TT-IR and TIE corroborated the Flame Atomic Emission Spectrometry (FAES) with 96 to 103% and

45 For Si(2)H(2), the antibonding intra-atomic energy changes that occur when the dibridged mole

46 n the bcc MPEA MoNbTi, enabled by the rugged atomic environment through which dislocations must navig

47 content was determined by Hydride Generation-Atomic Fluorescence Spectrometry (HG-AFS).

48 uorescence spectrometry and Hg by cold vapor atomic fluorescence spectrometry after ultrasound-assist

49 crude palm oil samples by hydride generation atomic fluorescence spectrometry and Hg by cold vapor at

50 light sheet fluorescence microscope with an atomic force microscope (AFM), providing simultaneous vo

51 thod uses piezoresponse force microscopy, an atomic force microscope modality that locally measures e

52 Applying strain gradients with an atomic force microscope tip polarizes an ultrathin film

53 ticular, we highlight the development of the atomic force microscope to investigate interactions with

54 Here we use a combination of noncontact atomic force microscopy (AFM) and density functional the

55 Atomic force microscopy (AFM) and transmission electron

56 We also provide a deeper focus into atomic force microscopy (AFM) applications that can brid

57 Here we demonstrate that atomic force microscopy (AFM) can be used to reshape, re

58 Here, we utilize atomic force microscopy (AFM) coupled with other methods

59 ies of key technological improvements turned atomic force microscopy (AFM) into a nanoscopic laborato

60 Previous nanoscale imaging by atomic force microscopy (AFM) showed that the ring-like

61 Here, we apply Atomic Force Microscopy (AFM) to quantitatively measure

62 we characterize using low-temperature (5 K) atomic force microscopy (AFM) with CO-terminated tips as

63 The AuNP-MIPs were investigated by employing atomic force microscopy (AFM), scanning electron microsc

64 iques such as optical and magnetic tweezers, atomic force microscopy (AFM), single-molecule fluoresce

65 ng topographically patterned substrates with atomic force microscopy (AFM).

66 the thickness of the deposits acquired from atomic force microscopy (AFM).

67 stiffness, and imaging were performed using atomic force microscopy (AFM).

68 Conductive probe atomic force microscopy (cAFM) was used to determine the

69 We have used high-speed atomic force microscopy (HS-AFM) and all-atom molecular

70 Here we used high-speed atomic force microscopy (HS-AFM) and kinetic modeling wh

71 Here, we use high-speed atomic force microscopy (HS-AFM), fluorescence recovery

72 Atomic force microscopy and cellular studies revealed th

73 bumin (BSA) was investigated at pH 3.0 using atomic force microscopy and differential scanning calori

74 Atomic force microscopy and scanning electron microscopy

75 ransistor has been studied with contact-mode atomic force microscopy and scanning Kevin probe microsc

76 elf-assembly pathways obtained using in situ atomic force microscopy are also discussed.

77 perties of these isoforms were studied using atomic force microscopy at high resolution in air and bu

78 Herein, we describe a simple atomic force microscopy based experimental procedure for

79 Atomic force microscopy data support the sequence-indepe

80 supramolecular polymer, light scattering and atomic force microscopy experiments show that water incr

81 an spectra and surface roughness obtained by atomic force microscopy images.

82 Here, we employed atomic force microscopy imaging in air and liquids to vi

83 ctions and self-association, as confirmed by atomic force microscopy imaging of proteins exhibiting t

84 To address this limitation, we applied atomic force microscopy infrared spectroscopy (AFM-IR) t

85 oretical results are confronted with QCM and atomic force microscopy measurements of positively charg

86 Atomic force microscopy on the resulting nanoscale toroi

87 Atomic force microscopy revealed 40-300 nm diameter OMVs

88 Atomic force microscopy revealed that MFS CMs are stiffe

89 Strikingly, atomic force microscopy reveals that many disc membranes

90 Atomic force microscopy reveals the Y269 residue is requ

91 Atomic force microscopy showed that the process of casei

92 Here, we used atomic force microscopy to visualize the interaction of

93 t 700 degrees C in 20 mTorr O(2) is shown by atomic force microscopy to yield nearly pinhole-free fil

94 Here we applied atomic force microscopy(7-12) to interrogate the morphol

95 super-resolution fluorescence microscopy and atomic force microscopy, a feat only obtained until now

96 scanning tunneling microscopy/spectroscopy, atomic force microscopy, and density functional theory c

97 cyclic voltammetry, square wave voltammetry, atomic force microscopy, and scanning electron microscop

98 , we apply an integrative approach combining atomic force microscopy, cryo-electron tomography, netwo

99 ectrochemical and electrical measurements in atomic force microscopy, we demonstrate that at a buried

100 Using atomic force microscopy, we find that during maturation,

101 Using atomic force microscopy, we quantified a 2.9-fold stiffe

102 Here, by PeakForce Tapping atomic force microscopy, we show that human XPA binds an

103 bining oxygen sensing, X-ray scattering, and Atomic Force Microscopy, we show that mammalian pulmonar

104 Using atomic force microscopy-infrared spectroscopy (AFM-IR),

105 ganded by Fab-epitope antibody fragments via atomic force microscopy.

106 nd homogeneity of the layer was evidenced by atomic force microscopy.

107 on with transmission electron microscopy and atomic force microscopy.

108 re characterized using optical microcopy and atomic force microscopy.

109 phology of OVT nanofibrils was studied using atomic force microscopy.

110 u(111) at 5 K, and imaged by high-resolution atomic force microscopy.

111 n-coated silica wafer was characterized with atomic force microscopy.

112 ng modulus, as measured by a method based on atomic force microscopy.

113 Here we show that noncontact atomic-force microscopy with a CO-terminated tip (used p

114 ted via association of two highly degenerate atomic gases(7,8).

115 ng and controlling interactions-in ultracold atomic gases, but also between quasiparticles, such as m

116 Atomic Hessian analysis, whereby the full Hessian is red

117 tmosphere where it is dissociated, producing atomic hydrogen, which is lost.

118 osphere, then dissociated by ions to produce atomic hydrogen.

119 for IAEs proves the magnetic nature of quasi-atomic IAEs through a transition from ferromagnetic [Gd(

120 lled carbon nanotubes as test tubes, and an 'atomic injector' coupled with aberration-corrected trans

121 Here, we provide atomic insight into a tug-of-war between cis/trans isome

122 e of the model with a 3D voxel and considers atomic interaction types and their energetic contributio

123 ational predictions of crucial hotspot inter-atomic interactions to validation using data on site-dir

124 Atomic interface regulation is thought to be an efficien

125 ntaining exclusive isolated In(delta+) -N(4) atomic interface sites for CO(2) electroreduction to for

126 ng collective quantum spin models, where the atomic internal levels mimic a spin degree of freedom an

127 iguing ferromagnetism originating from quasi-atomic interstitial electrons in low-dimensional materia

128 r ion and the internal states of a (40)Ca(+) atomic ion(2).

129 chiral molecular ligands, which bind to the atomic/ionic components of the crystals, preferentially

130 ns can become comparable to the normal intra-atomic Kalpha-emission signal.

131 Here we show that an atomic layer deposition derived V(2) O(5) can be an exce

132 In this paper, we applied a modified atomic layer deposition procedure that is able to passiv

133 Here, a modified atomic layer deposition technique was developed to achie

134 to monitor and control metal oxide growth in atomic layer deposition, and we include data for SiO(2)

135 e can be deposited in a controlled manner by atomic layer deposition, they show excellent interface p

136 ified CeO(2) supports based on redox-coupled atomic layer deposition.

137 t have been deposited onto MgAl(2)O(4) using atomic layer deposition.

138 rface synthesis, this work proposes a single-atomic-layer organic semiconductor with a wide band gap

139 in situ on-site transformation of V(2) O(5) atomic layers into Zn(3) V(2) O(7) (OH)(2) .2 H(2) O (ZV

140 N(4) This monolayer was built up by septuple atomic layers of N-Si-N-Mo-N-Si-N, which can be viewed a

141 s from the opposite orientations of adjacent atomic layers, whereas this effect is limited in BP latt

142 between covalent bonding taking place at an atomic level and colloidal bonding occurring at the leng

143 red and long-range ordered structures at the atomic level is extremely rare and so far has only been

144 However, atomic level study of PbI(2) monolayer has been limited

145 requires engineering electrocatalysts at the atomic level, which is a grand challenge.

146 that has not been well characterized at the atomic level.

147 enging due to poor structural control at the atomic level.

148 ontrol the catalytically active sites at the atomic level.

149 iodicity and reproducibility of pores at the atomic level.

150 lear and remain unobserved in action, at the atomic level.

151 ls the residue environment as a graph at the atomic level.

152 evolution of Fe-N bonds was examined at the atomic level.

153 ized by various experimental techniques, the atomic-level contributions of various secondary structur

154 dispersed bimetallic cluster catalysts with atomic-level control of dopants has been a long-standing

155 e-scale cryo-EM-based structure modeling and atomic-level density map-guided structure refinement.

156 Collectively, our results establish an atomic-level description of the underlying mechanism reg

157 The present structure reveals atomic-level detail in capsid architecture and provides

158 precedented ability of computations to probe atomic-level details of catalytic systems holds immense

159 tions are used to capture the energetics and atomic-level details of Mg(2+)-RNA interactions that occ

160 Molecular dynamics provide atomic-level insight into the loop configurations.

161 ar Dynamics (MD) simulations seek to provide atomic-level insights into conformationally dynamic biol

162 ensive structural analyses have revealed key atomic-level interactions between the SARS-CoV spike pro

163 simulations reveal that the introduction of atomic-level interfaces can lower the oxidation overpote

164 Since the advent of protein crystallography, atomic-level macromolecular structures have provided a b

165 to a critical lack of methods to probe their atomic-level microstructure.

166 wide, computational assessment of changes to atomic-level physicochemical properties and of oxidative

167 alculations was used to unravel the complete atomic-level random Bi(3+)/In(3+) cationic mixing in Cs(

168 to fold into structures with high fold- and atomic-level similarity to their corresponding native st

169 lation influences arrestin behavior by using atomic-level simulations and site-directed spectroscopy

170 receptors using different techniques, define atomic-level structures of virus-glycan complexes, and s

171 Atomic-level three-dimensional (3D) structure data for b

172 assembling properties and pave the way to an atomic-level understanding of amyloid inhibition.

173 sign of multicomponent nanocrystals requires atomic-level understanding of reaction kinetics.

174 tection of the energy difference between two atomic levels, which is measured in terms of the quantum

175 derstanding of hair cell MT at molecular and atomic levels.

176 ed that the compounds have in common a local atomic-like state that is well described by the U [Formu

177 rbon precursor, C(18)Br(6), in 64% yield, by atomic manipulation on a sodium chloride bilayer on Cu(1

178 hat the restriction of our pure state to any atomic masa [Formula: see text] of diagonal operators wi

179 value, zeta, is calculated using an assigned atomic mobility value within each repeat unit.

180 Here we report the atomic model of the complete R2 pyocin in its pre-contra

181 secondary structural elements and produce an atomic model of the intermediate, comprising 120 copies

182 The data were used to build an atomic model of the tropomyosin cable that fits onto the

183 py, permitting building of a nearly complete atomic model.

184 From these structures, we identify and build atomic models for 30 proteins, including 23 radial-spoke

185 Identifying unambiguous atomic models for oxyfluorides, needed for materials des

186 s, (b) RAG Builder: builds three-dimensional atomic models from candidate graphs generated by RAG Sam

187 r-dynamics-based methods for building pseudo-atomic models in a semi-automated fashion.

188 Pseudo-atomic models indicate that GCP4, GCP5, and GCP6 form di

189 s, each containing 384 subunits of 11 unique atomic models of 10 gene products.

190 Atomic models of 103 of the known human AT1R polymorphis

191 nal structural-biology approaches, to obtain atomic models of multiple protein complexes implicated i

192 Compelling atomic models of troponin-tropomyosin-actin were publish

193 state-of-the-art microscopy directly images atomic/molecular configurations in thin crystals from ch

194 a powerful computational method for studying atomic/molecular-scale movement and interactions.

195 sonances, we show how detailed properties of atomic motions and energy redistribution can be unveiled

196 s) in combination with functional assays and atomic mutagenesis.

197 y interaction with the nanoscale ensemble of atomic nuclear spins, which is particularly problematic

198 to charge-symmetry-breaking forces acting in atomic nuclei.

199 study the behavior of matter denser than an atomic nucleus and to measure the expansion rate of the

200 ron-positron pairs in a solid foil with high atomic number.

201 istent field wave function in terms of quasi-atomic orbitals.

202 '/ L(2)) intensity ratio, which reflects the atomic order in the first Ca coordination shell, we dete

203 The atomic origins of this light are demonstrably poorly und

204 tally validated angstrom-level 3D picture of atomic pathways thus far only conjectured through DFT ca

205 ystals, leading to the surface enrichment of atomic Pd instead of formation of particles.

206 The lattice interference and perturbation of atomic periodicity at the perovskite surfaces often sign

207 on in real time, revealing key stages of the atomic permeation.

208 he imaging and the interference technique in atomic physics.

209 ur ab initio calculations reveal two extreme atomic-physics phenomena-firstly, an interspecies radiat

210 be measured by contacting the molecule with atomic precision and forming a molecular bridge between

211 nanocrystals for specific applications, full atomic precision may not be needed.

212 be analyzed, understood, and controlled with atomic precision, a key characteristic of molecules.

213 cluster-based devices can be fabricated with atomic precision.

214 xcitation energy due to entanglement between atomic quantum system and electronic quantum system.

215 ear relation between the carbon to zirconium atomic ratio (C/Zr) and the lattice parameter, in contra

216 In this study, the relationship between C/Zr atomic ratio and the lattice parameter is critically ass

217 oscale size of moire domains, the effects of atomic reconstruction on the electronic and excitonic pr

218 and Zika virus) particles are known to near-atomic resolution and show detailed structure and arrang

219 alpha bound to phosphorylated Ric-8A at near atomic resolution by cryo-electron microscopy and X-ray

220 ify and localize biomolecular frustration at atomic resolution by examining the statistics of the ene

221 cular dynamics simulations can provide novel atomic resolution details regarding mechanostability and

222 n nanotube one-by-one has been achieved with atomic resolution in real time, revealing key stages of

223 croscopy (SP-cryo-EM) routinely reaches near-atomic resolution of isolated complexes.

224 ation of such transient weak interactions at atomic resolution remains challenging.

225 d investigated with electron diffraction and atomic resolution scanning transmission electron microsc

226 use of the transient subunit association, an atomic resolution structure of an active alpha2beta2 RNR

227 Here, we determine the atomic resolution structures of dimeric, tetrameric, and

228 etics and equilibria of chemical exchange at atomic resolution, including relaxation dispersion, exch

229 At atomic resolution, it becomes possible to extend frustra

230 ophila melanogaster at subnanometer and near-atomic resolution, respectively.

231 nese-based ferromagnetic kagome lattice with atomic resolution.

232 INSTIs dolutegravir and bictegravir at near-atomic resolution.

233 c investigation of restructuring dynamics at atomic resolution.

234 ructures of Msp1-substrate complexes at near-atomic resolution.

235 gnal transduction in the cGAS pathway at the atomic resolution.

236 sed to determine the amyloid-CR interface at atomic resolution.

237 ely paints a picture of STING signaling with atomic resolution.

238 s have had their structures characterized at atomic resolution.

239 ion in nanoscale and biological systems with atomic resolution.

240 bles the detection of single metal atoms and atomic-resolution imaging of the iron core of ferritin m

241 Atomic-resolution imaging reveals the coexistence of two

242 d the potential to make the determination of atomic-resolution RNA ensembles routine.

243 Here we present near-atomic-resolution structures of human and frog PANX1 det

244 Our studies provide atomic-resolution structures of the PP-IP products and u

245 Atomic-resolution studies for these molecules are essent

246 Methyl-NMR enables atomic-resolution studies of structure and dynamics of l

247 lm via in situ ion irradiation studied using atomic-resolution transmission electron microscopy (TEM)

248 Here, using atomic-resolution, time-resolved in-situ environmental t

249 in complex with cyclophilin A (CypA) at near-atomic resolutions.

250 t is typically limited because motion at the atomic scale follows stochastic processes.

251 -decorated F-actin-tropomyosin together with atomic scale protein-protein docking of tropomyosin to t

252 ng of the initial steps of nucleation at the atomic scale.

253 ents in chemistry and material sciences, the atomic-scale description of the initial photoinduced pro

254 Complex crystal structures with subtle atomic-scale details are now routinely solved using comp

255 energy and makes it possible to observe the atomic-scale dynamics in a timescale of picoseconds.

256 Using dynamic, atomic-scale electron microscopy observations and theore

257 Here we demonstrate atomic-scale GB phase coexistence and transformations at

258 Atomic-scale imaging combined with deep neural network a

259 Here, using a combination of atomic-scale imaging, simulations and classical nucleati

260 ations throughout the self-assembly provided atomic-scale information on the thickness of the [(SnSe(

261 show for the first time that non-equilibrium atomic-scale lattice defects can be detected in nanopart

262 s and theoretical modeling, we delineate the atomic-scale mechanisms associated with the nucleation,

263 In contrast, here we report an atomic-scale nonchemical dealloying process that results

264 are employed to identify the 3D nature of an atomic-scale ordering of liquid Ga in contact with solid

265 Here we show, using atomic-scale quantitative imaging and correlative spectr

266 However, the atomic-scale regulation of such active sites for NRR cat

267 phases can be kinetically trapped, enabling atomic-scale room-temperature observations.

268 pe optimized force field (AWSEM), we predict atomic-scale structures for several tripartite SMC-kleis

269 By comprehensive characterizations from atomic-scale structures to large-scale device performanc

270 d, insulating, amorphous metal oxyhydroxide, atomic-scale thin interlayer (ca. 3 nm) between the TCO

271 situ magneto-structural characterization and atomic-scale tracking of hydrogen atoms reveal that the

272 s, and, ultimately, energy harvesting at the atomic scales.

273 ate the origin of the switching mechanism in atomic sheets using monolayer MoS(2) as a model system.

274 observation of ultrafast processes with near-atomic spatial resolution.

275 xciting class of 2D materials with different atomic species on their upper and lower facets.

276 probe the local environment around specific atomic species.

277 ical processes with ultrafast resolution and atomic specificity.

278 ) materials often vary dramatically with the atomic stacking order between layers, but this order can

279 ce of electron correlations in these excited atomic states.

280 ronic phenomena due to the interplay between atomic structure and electron correlations.

281 m a theory perspective owing to their unique atomic structure and exotic materials properties, but li

282 Characterization and understanding of their atomic structure and structure-property relationships ar

283 The atomic structure of a germanium doped phosphorous seleni

284 are required to quantitatively determine the atomic structure of complex nanostructured materials.

285 We have now determined the atomic structure of the C. jejuni G508A flagellar filame

286 esign small peptidic inhibitors based on the atomic structure of the core of alpha-syn fibrils.

287 Understanding the connection between the atomic structure of the surface and the interfacial elec

288 m onto suspended graphene supports to enable atomic structure study of PbI(2).

289 adult heads and determined its activity and atomic structure, at 2.6-angstrom resolution, using cryo

290 ehavior, we have thoroughly investigated the atomic structures and lattice dynamics by combining neut

291 d by latency-a hallmark of EBV infection-and atomic structures are thus available only for recombinan

292 Although recent atomic structures have provided snapshots on a number of

293 ent paper, Ciudad et al. elucidate the first atomic structures of Abeta oligomers, which reveal how t

294 We resolved electron cryomicroscopy atomic structures of Pf4 with and without its linear sin

295 Here, we present the near-atomic structures of the BBSome by itself and in complex

296 We present atomic structures of these nAbs bound to all three viral

297 ield have achieved such precise control over atomic systems that gravity, often negligible when consi

298 evable in mechanical, acoustic, or ultracold atomic systems, and even with electron beams.

299 the quantum control of its interaction with atomic systems.

300 While atomic tunneling has been invoked to explain the low-tem