ライフサイエンスコーパス: diffusion process

1 rinsically organized, possibly by a reaction-diffusion process.

2 lecular morphogens interacting in a reaction-diffusion process.

3 u, even at 640 micro M, suggesting a passive diffusion process.

4 lier results based on the Ornstein-Uhlenbeck diffusion process.

5 zes the conformational space searched in the diffusion process.

6 are modeled by analogy to an effective eddy diffusion process.

7 ort on the lattice is modelled by a discrete diffusion process.

8 f these radicals play a critical role in the diffusion process.

9 forms, modeled as a "wave-pinning" reaction-diffusion process.

10 lectric memory hardware for the neuromorphic diffusion process.

11 In contrast, forgetting is slow, driven by a diffusion process.

12 ic algorithm and then simulated the recovery diffusion process.

13 an image, evolves smoothly across the whole diffusion process.

14 lide diffusion does not follow the classical diffusion process.

15 rypt spacing identifies evidence for a crypt diffusion process.

16 light on a fundamental understanding of the diffusion process.

17 al autocorrelation observed in the empirical diffusion process.

18 controlled by a kinetically governed cation diffusion process.

19 shortest paths and dynamical features of the diffusion process.

20 eviation and other responses by the standard diffusion process.

21 hree clades followed a heterogeneous spatial diffusion process.

22 ay substantially slow down or facilitate the diffusion process.

23 nter likelihood throughout the network via a diffusion process.

24 saccharides to pass through by a facilitated diffusion process.

25 n a seed but fast enough to beat the surface diffusion process.

26 ted to better outcomes during the technology diffusion process.

27 otential explanatory predictors of the viral diffusion process.

28 ductivity of LFS, thus improve the Li(+)-ion diffusion process.

29 the surface and bulk pathways to the overall diffusion process.

30 system is independent of the details of the diffusion process.

31 genetic/epigenetic alteration rates act as a diffusion process.

32 dealizing hillslope transport as a nonlinear diffusion process.

33 radically change the estimation of classical diffusion processes.

34 urately account for the effect of rho on the diffusion processes.

35 rs in heterogeneous electrochemical reaction-diffusion processes.

36 ontrast to the behavior seen for equilibrium diffusion processes.

37 many elementary steps, usually convoluted by diffusion processes.

38 imitations of uniform disorder and Markovian diffusion processes.

39 esired flexibilities, which are key to guest diffusion processes.

40 random walk, the two most typical anomalous diffusion processes.

41 ion, differentiation, death, and migration / diffusion processes.

42 vich equations, suggesting chemisorption and diffusion processes.

43 ructure of materials and the resultant ionic diffusion processes.

44 mission in rural areas to follow predictable diffusion processes.

45 raph for epidemic transmission based on pure diffusion processes.

46 ased efficiencies and yields in reaction and diffusion processes.

47 nder out-of-equilibrium conditions involving diffusion processes.

48 embedded in a solution with complex reaction-diffusion processes.

49 non-equilibrium fluctuations develop during diffusion processes.

50 nfluenced by osmosis, buoyancy, and reaction-diffusion processes.

51 ration of ligands, is affected by stochastic diffusion processes.

52 cribe the dehalogenation, recombination, and diffusion processes.

53 ng the initial microstructure and subsequent diffusion process, a higher performance magnet is expect

54 We find that the backward diffusion process acting after a time t is governed by a

55 re, severe lattice distortions, and sluggish diffusion processes afford large phase space for perform

56 steady-state equilibrium with an additional diffusion process allowing Abeta deposits to diffuse ove

57 es may evolve from neutral macroevolutionary diffusion processes alone.

58 inetics could be modeled by a conformational diffusion process along a single-well free energy profil

59 cribes the role of individual nodes during a diffusion process and can identify structural modificati

60 Lys groups appear to have a role in the H(+) diffusion process and chemically modifying them blocks t

61 a novel Bayesian framework to model a latent diffusion process and estimate the joint likelihood of t

62 er/silane interface exists during the entire diffusion process and is lost when the silane molecules

63 ic forces play a pivotal role in driving the diffusion process and must be taken into account when co

64 rlo simulations, which reveal details of the diffusion process and provide insight into conditions at

65 This regulates Zn(2+) diffusion process and restricts its accessibility to Zn(

66 led this process by a simple one-dimensional diffusion process and stochastic Langevin dynamics.

67 tomography has identified the direct lithium diffusion process and the electrode wetting by the elect

68 both the hypothetical expected time scale of diffusion process and the long time delay observed in th

69 ch cohort modeled separately as an advection-diffusion process and the total cell density determining

70 ing-based, nanometer-scale analysis of local diffusion processes and long-range coordinated movements

71 anic optoelectronic devices, sputter-induced diffusion processes and roughness formation have only be

72 ivial connection between stochastic reaction-diffusion processes and spatio-temporal Cox processes, a

73 abilities, using a numerical solution of the diffusion process, and assuming independent binomial sam

74 , which integrates structural positions, the diffusion process, and, most importantly, relevant node

75 ntervention in silico, simulated information diffusion processes, and generated emergent information

76 Our approach is based on the diffusion process approximation and the resulting mathem

77 wever, proton delocalization and the overall diffusion process are not necessarily correlated.

78 Diffusion processes are central to human interactions.

79 Diffusion processes are governed by external triggers an

80 Precipitation, desorption, and diffusion processes are insufficient or in the wrong dir

81 On the one hand, these linear diffusion processes are mediated by long-range electrost

82 such a manner that the coupled reaction and diffusion processes are propagated through time efficien

83 Stochastic reaction-diffusion processes are widely used to model such behavi

84 Diffusion processes are widespread in biological and che

85 nsive molecular statics calculations of pipe diffusion processes around irregular prismatic loops are

86 elf-assembly, self-organization and reaction-diffusion processes as essential features of cells.

87 o a recently introduced CSD derived from the diffusion process associated with the coalescent with re

88 ming independent binomial sampling from this diffusion process at each time point.

89 The direct experimental characterization of diffusion processes at nanoscale remains a challenge tha

90 t future directions for research on reaction-diffusion processes at the nano- and microscales that we

91 ing electrode allows for precise analysis of diffusion processes at the vicinity of the cell membrane

92 , and that epidemic spread follows a spatial diffusion process based on geographic proximity.

93 rs) were prepared via a spontaneous reaction-diffusion process based on periodic precipitation.

94 -based measurements of intracellular binding-diffusion processes, based on a closed-form equation of

95 Subsequent diffusion processes between languages in Sulawesi appear

96 ads to protein crowding that impedes lateral diffusion processes but is required for efficient light

97 lular space describes hindrance posed to the diffusion process by a geometrically complex medium in c

98 SiteAF3 refines the diffusion process by fixing the receptor structure and o

99 analysis approach can be used to investigate diffusion processes by MS imaging in general.

100 In the majority of cases, the diffusion process can be adequately described by Fick's

101 onstrate that the hardware-based true random diffusion process can be implemented for image generatio

102 It is shown that the VI diffusion process can be suppressed by controlling the a

103 We show how designed reaction-diffusion processes can likewise produce precise pattern

104 the Fisher-Kolmogorov framework of reaction-diffusion processes captures the observed fluctuations i

105 can be understood in terms of a simple jump-diffusion process, combining standard diffusion with Poi

106 By picking a set of source nodes, a diffusion process covers a portion of the network.

107 should interact multiplicatively because the diffusion process depends on the signal-to-noise ratio.

108 vivo than compared to in vitro, and a simple diffusion process describes the autocorrelation function

109 revealed to significantly affect the exciton diffusion process, determined by temperature-dependent p

110 placenta are driven by a variety of flow and diffusion processes, diffusion-weighted MRI could enhanc

111 rate slowly increases with temperature as a diffusion process, dramatic jumps are observed at 14.7 d

112 eveal how growth, by tinkering with reaction/diffusion processes, drives the diversification of tooth

113 onsted acid sites in the 8-ring enhances the diffusion process due to the formation of a favorable pa

114 y governed by the Fourier's law describing a diffusion process due to the short wavelength and mean f

115 The crypt diffusion process enables accommodation of the additiona

116 onditional neural field encoding with latent diffusion processes, enabling memory-efficient and robus

117 hms in a framework concerning: (1) different diffusion process - Epidemics, Information, and Rumor mo

118 The diffusion process followed by a passive tracer in protot

119 We show that ABLD is the governing diffusion process for the continuous leaching of phthala

120 r strategy unlocks the potential of reaction-diffusion processes for the manufacturing of uniformly l

121 ment for the self-similar behavior of such a diffusion process, for which an exact self-similar analy

122 ime evolution takes place through a reaction-diffusion process, for which we develop a model that inc

123 se problem of learning a stochastic reaction-diffusion process from data.

124 hen propagated in the cytosol via a reaction-diffusion process from the endoplasmic reticulum.

125 r a variety of conditions that decoupled the diffusion process from the heparan sulfate binding pheno

126 ting technique to decouple the sedimentation-diffusion process from the reaction process.

127 assical SIR model by including mutation as a diffusion process in a phenotype space of variants.

128 n permeation is modeled as a continuum drift-diffusion process in a self-consistent electrostatic pot

129 al model that describes the coupled reaction-diffusion process in an established immunological synaps

130 to compare different properties of the water diffusion process in brain tissues, using different cont

131 eedom as well as to evaluate the rate of the diffusion process in competition with the backward react

132 etically limited by the sluggish solid-state diffusion process in electrode materials.

133 d loss of DNA over time may be due to a bulk diffusion process in many cases, highlighting the import

134 In this work, this diffusion process in nonideal ALD is investigated and ex

135 s with their signaling pathways using a heat diffusion process in protein-protein interaction (PPI) n

136 A facilitated diffusion process in which a DBP combines three-dimensio

137 s a major model system for studying reaction-diffusion processes in biology.

138 However, because anomalous diffusion processes in complex systems are usually not s

139 ord frequencies, and how they are related to diffusion processes in directed networks, or aging proce

140 hting the key role played by long-term fluid diffusion processes in driving the occurrence of earthqu

141 properties and the presence of bias of such diffusion processes in each of its applications.

142 tice simulations, hydrodynamic interactions, diffusion processes in high-viscosity environments, and

143 easily implemented to the study of reaction-diffusion processes in live bacteria despite their small

144 Many diffusion processes in nature and society were found to

145 tical approach for controlling acid reaction/diffusion processes in photolithography.

146 ed volume effects in the context of reaction-diffusion processes in porous networks may lead to unexp

147 The knowledge of diffusion processes in semiconducting alloys is very imp

148 latform to accelerate mass-transport-limited diffusion processes in small-volume heterogeneous reacti

149 pectively) indicate a mechanism dominated by diffusion processes in these cases.

150 mistries, stochastically treats reaction and diffusion processes in three spatial dimensions, accurat

151 ery time with respect to the calculations of diffusion processes inside each phase from the first lay

152 exogenous lipid infusion, this interstitial diffusion process is curtailed.

153 A model of the adsorption/diffusion process is developed to provide a description

154 counterpart by 0.2 eV that the bottleneck of diffusion process is for oxygen vacancies to escape equa

155 The diffusion process is guided by a combination of scalar p

156 (2) If the diffusion process is interrupted, as in a cued-response

157 The diffusion process is modeled to calculate diffusion coef

158 SECM mode of operation is that the feedback diffusion process is not required for the measurement, a

159 bove 200 K and the activation energy for the diffusion process is obtained as [Formula: see text] meV

160 The molecular nature of this diffusion process is poorly understood.

161 In particular, a diffusion process is shown to hold for the average allel

162 tanding biochemical model whereby a reaction-diffusion process is templated by recently formed ommati

163 ing the initial stages of CE, suggesting the diffusion process is the fundamental mechanism of CE in

164 tubulin tails and tail modifications in the diffusion process is unclear.

165 In all cases, the diffusion process is well-described by a refined version

166 The study of reaction-diffusion processes is much more complicated on general

167 S) to distinguish between different types of diffusion processes is often a perilous undertaking beca

168 persed in oil, and demonstrate that reaction-diffusion processes lead to chemical differentiation, wh

169 Reaction-diffusion processes lead to complex nonequilibrium patte

170 These findings can be explained by diffusion processes leading to a sample surface configur

171 ovide a real example of the kind of reaction-diffusion process long predicted to be a mechanism of pa

172 growth the balance between kinetics and the diffusion process may lead to fast, enhanced hydrodynami

173 recover the threshold behavior by analyzing diffusion processes mediated by real human commuting dat

174 neral approach to the description of electro-diffusion processes, namely, Nernst-Planck-Poisson (NPP)

175 the picosecond annealing and the nanosecond diffusion processes observed experimentally.

176 all diffusion of inorganic ions is a Fickian diffusion process occurring through rubbery amorphous po

177 ures affect dramatically the behavior of the diffusion processes occurring on networks, determining t

178 we investigate for the first time the charge diffusion processes occurring upon two sequential one-el

179 metastable state occurring in the transient diffusion process of hydrogen, despite the absence of hy

180 ation in redox signal results from the lower diffusion process of ions during redox reaction after pr

181 lices reveals detailed information about the diffusion process of lipids in the acetabular cup and pr

182 icantly reduce energy consumption during the diffusion process of sodium ions, while the carbon-coate

183 Phylogenetic analyses and trait diffusion process of these sequences were performed usin

184 ables selectivity through the adsorption and diffusion processes of ALD precursors, distinctly differ

185 sualization of the interfacial evolution and diffusion processes of different polysulfides that demon

186 Self-diffusion processes of small atoms or ions play a crucia

187 network specifically for a disease through a diffusion process on a gene-gene similarity matrix deriv

188 meter values, this index is linked to a heat diffusion process on a graph and therefore encodes geome

189 ffectively characterized by a mean-reverting diffusion process on a logarithmic scale.

190 ts of a motor enzyme are well described by a diffusion process on a two-dimensional potential energy

191 hese data are consistent with a conformation diffusion process on the folding energy landscape, in ac

192 We study the dynamics of reaction-diffusion processes on heterogeneous metapopulation netw

193 of tissue, our goal is to examine intravoxel diffusion processes on the order of picoliters.

194 nthesizing a network that implements a drift-diffusion process over a ring-shaped manifold.

195 data distributions by reversing a Markovian diffusion process, progressively denoising Gaussian nois

196 his impressive research, to date, the ligand diffusion processes remain unclear and controversial.

197 ealing time, makes it possible to bypass the diffusion processes responsible for decomposition.

198 w that this coupling significantly slows the diffusion process, resulting in dynamic trapping of info

199 tailed numerical simulations of the reaction-diffusion process reveal that a shallow gradient of enzy

200 e signature of several biologically relevant diffusion processes (simple diffusion, continuous-time r

201 dynamic electron fluid supports a nonthermal diffusion process-such as an imbalance mode between diff

202 g to a stochastic two-state Markov switching-diffusion process that depends on the strength of the we

203 nts, and the goal is to infer the underlying diffusion process that generated the data.

204 t to model evolution of features as a linear diffusion process that progresses with increasing geneti

205 To enable this, we introduce a diffusion process that respects the conformational stati

206 throughout the full (1)H reservoir via spin-diffusion processes that act as analogues of chemical ex

207 rived to characterize different ensembles of diffusion processes that are indistinguishable by existi

208 pecifically, we discuss examples of reaction-diffusion processes that lead to such outcomes as self-a

209 declined on stream because of dynamic metal diffusion processes that led to a more uniform alloy str

210 Here we show that diffusion processes that occur far away from equilibrium

211 ase.DNA interactions, reflecting facilitated diffusion processes, that occur prior to EcoRI sequence

212 Through a reaction-diffusion process, the hydrophobic region expands with a

213 oxide ion dynamics in the material: a slower diffusion process through the Bi-O sublattice and a fast

214 Pt adsorption sites by an activated surface diffusion process through the CoO shells surrounding app

215 posed by diffusion, analysis is developed of diffusion processes through stirred and unstirred media,

216 by effectively reducing a three-dimensional diffusion process to a spatially constrained, two-dimens

217 scribes the use of a nonequilibrium reaction-diffusion process to achieve the synthesis of a multifun

218 lified photoresists, uses a complex reaction-diffusion process to delineate patterned areas with high

219 one-choice RT tasks that uses a one-boundary diffusion process to represent the accumulation of stimu

220 e employed for the investigation of reaction-diffusion processes to additionally include cases in whi

221 t into the physical parameters affecting the diffusion process, to allow for more efficient and targe

222 porates a number of fundamental reaction and diffusion processes, treated in a fully stochastic manne

223 The advection-diffusion processes underlying ACTIS can be described by

224 t process for the sampled chromosomes with a diffusion process used to model the evolution of the dis

225 ing transmission-potential as an approximate diffusion process using a path-wise series expansion of

226 hod to extract an accurate assessment of the diffusion process using many short trajectories with a s

227 Hopfield Neural Network (HNN) carry out the diffusion process using the suggested encryption method.

228 rica and statistically model spatio-temporal diffusion processes using different combinations of puta

229 resenting the levels of the two chemicals by diffusion processes, we assume their interaction is gove

230 To create a mathematical model of these diffusion processes, we have chosen as an example hydrog

231 In the past, diffusion processes were not accounted for, thereby posi

232 ce suggest that sliding involves a DNA twist-diffusion process whereby the DNA rotates about the heli

233 tivity are totally dependent on the Brownian diffusion process, which has greatly hindered their effi

234 sistent with a nonzero starting value of the diffusion process, which increases and decreases decisio

235 efficient method to stochastically simulate diffusion processes, which at the same time allows synch

236 described by a classical, Einstein-type, 1D diffusion process with a diffusion coefficient of 2.710(

237 is telomere dynamics onto a biased branching-diffusion process with an absorbing boundary condition w

238 easure the spatial evolution of the reaction-diffusion process with nanometer resolution.

239 ring these intervals is shown to be given by diffusion processes with a diffusion coefficient that de

240 strategically positioned residues alter the diffusion processes within hemoglobin's subunits and sug

241 acterize heterogeneous and anisotropic water diffusion processes within macroscopic MRI voxels non-in

242 recovery from hazards occurs through various diffusion processes within social and spatial networks o

243 y directly simulating competing reaction and diffusion processes within the oxide film using kinetic