ライフサイエンスコーパス: fluid dynamic

1 tion, graft apposition, and tissue interface fluid dynamics.

2 an affect light transport in ways resembling fluid dynamics.

3 surface tension, gravity, and incompressible fluid dynamics.

4 s a particularly important route to chaos in fluid dynamics.

5 ments of interest (n=142) with computational fluid dynamics.

6 rgent properties determined by the resulting fluid dynamics.

7 n incorrect application of the principles of fluid dynamics.

8 time points through the use of computational fluid dynamics.

9 ing simulation models based on computational fluid dynamics.

10 es for pulmonary diseases involving abnormal fluid dynamics.

11 ta assimilation, for example, in geophysical fluid dynamics.

12 ns can be well described using computational fluid dynamics.

13 of the beam power distribution to the local fluid dynamics.

14 ated by noradrenaline drive the intracranial fluid dynamics.

15 emodynamics were quantified by computational fluid dynamics.

16 omedical evaluations of vascular and airways fluid dynamics.

17 end practical applications-in this instance, fluid dynamics.

18 eter that integrates population dynamics and fluid dynamics.

19 nfarction, suggesting dysregulation of brain fluid dynamics.

20 ty waves; as predicted by recent advances in fluid dynamics.

21 ore structures, thereby impacting pore-scale fluid dynamics.

22 s to generate accurate predictions of tumour fluid dynamics.

23 to the more complex and unexplored domain of fluid dynamics.

24 thin-layer limit, or "lubrication limit", of fluid dynamics.

25 essential yet long-neglected by traditional fluid dynamics.

26 ferent climatic conditions via computational fluid dynamics.

27 annel, which were confirmed by computational fluid dynamics.

28 ned using microtomography with computational fluid dynamics.

29 Two-dimensional electro-fluid-dynamic (2-D EFD) devices, in which both electric

30 ally be used to monitor how the interstitial fluid dynamics affect cancer microenvironment and plasti

31 We use a computational fluid dynamics algorithm capable of simulating 10-nanome

32 a local workstation by using a computational fluid dynamics algorithm.

33 science, biomedical engineering, multiphase fluid dynamics, among other fields.

34 Computational fluid dynamic analysis demonstrated increased velocity a

35 Feedback from early trials and computational fluid dynamic analysis guided device design optimization

36 ng Fontan can be calculated by computational fluid dynamic analysis using 3-dimensional MRI anatomic

37 Here, by applying experimental fluid dynamics analysis and mathematical modeling, we pr

38 ere we report on a family-wide computational fluid dynamics analysis of all eight hammerhead shark sp

39 We used computational fluid dynamics analysis to assess hemodynamic parameters

40 It is believed that fluid dynamic and thermodynamic behavior differ signific

41 ssure calculations, using both computational fluid dynamics and a newly developed method from empiric

42 We combine fluid dynamics and advanced in situ transmission electro

43 ultiscale mathematical model that integrates fluid dynamics and an intracellular insulin signaling pa

44 try) and mathematically (using computational fluid dynamics and analytical mathematical models).

45 odel relied on the coupling of computational fluid dynamics and biochemical kinetics, and was validat

46 Computational fluid dynamics and density functional theory simulations

47 tigate a range of hypotheses for the systems fluid dynamics and establish a theoretical model to pred

48 Fluid dynamics and evolutionary biology independently pr

49 haracteristics in humans using computational fluid dynamics and frequency-domain optical coherence to

50 ive approach, a combination of computational fluid dynamics and high-resolution micro-CT imaging, rev

51 Recent advances in computational fluid dynamics and image-based modeling now permit deter

52 y and verified with the aid of computational fluid dynamics and kinetic simulations.

53 A coupled computational fluid dynamics and mass transfer model was applied to pr

54 The analysis describes the characteristic fluid dynamics and mass transport effects occurring in a

55 model that provides a deep understanding of fluid dynamics and mass transport in the EOPPP method, a

56 Here, a fully-coupled fluid dynamics and microstructure modelling is developed

57 At the apex, microscale fluid dynamics and nanoscale channel dynamics must also

58 ing fundamental open problem in mathematical fluid dynamics and nonlinear partial differential equati

59 g study using a novel combined computational fluid dynamics and physiologically based PK model was ap

60 Fluid dynamics and solids mechanics should be considered

61 odelling the coupling between heat transfer, fluid dynamics and surface reaction kinetics.

62 tic field, and study the micro-environmental fluid dynamics and their effect on tumor growth by accou

63 ll organs, responsible for maintaining organ fluid dynamics and tissue homeostasis.

64 terize their efficacy, such as computational fluid dynamics and urban canopy models, are computationa

65 Here we present data from computational fluid dynamics and video endoscopy in suspension-feeding

66 s using analytic approaches of computational fluid dynamics and/or continuum chemical dynamics.

67 ation of vapour in liquids, is ubiquitous in fluid dynamics, and is often implicated in a myriad of i

68 its complex physics involving heat transfer, fluid dynamics, and phase changes.

69 We draw on the fields of biomechanics, fluid dynamics, and robotics to demonstrate that there i

70 A computational fluid dynamics approach was taken, solving the Navier-St

71 The three-dimensional intracochlear fluid dynamics are coupled to a micromechanical model of

72 Early fluid dynamics as measured by (1) early RFI volatility a

73 of a major life history event in response to fluid-dynamic attributes of a target environment.

74 Computational fluid dynamics based on finite element analysis was used

75 annot be analyzed directly and most of their fluid dynamic behavior is reconstructed by the deposits

76 now a widely used approach for computational fluid dynamics, building greater understanding of its nu

77 the dual-pulse to control the plasma-driven fluid dynamics by adjusting the axial offset of the two

78 sing first-principle chemistry, physics, and fluid dynamics, calibrated from depuration experiments.

79 Intraventricular fluid dynamics can be assessed clinically using imaging.

80 ich it is exposed, we employed computational fluid dynamic (CFD) analysis of the luminal geometry fro

81 A computational fluid dynamic (CFD) model was used to optimize the desig

82 Computational fluid dynamic (CFD) simulations using the libraries of O

83 By use of computational fluid dynamic (CFD) software with turbulence modeling, t

84 r feeding is inconsistent with computational fluid dynamics (CFD) and analytical estimates.

85 Computational fluid dynamics (CFD) can be used for non-invasive evalua

86 Computational fluid dynamics (CFD) can be used to simulate vascular ha

87 ensional modelling approach of Computational Fluid Dynamics (CFD) coupled with the Discrete Element M

88 Image-based computational fluid dynamics (CFD) has become a new capability for det

89 Computational Fluid Dynamics (CFD) has emerged as a key tool in unders

90 A three-dimensional computational fluid dynamics (CFD) model analyzes the optimized ROKSM

91 We present a computational fluid dynamics (CFD) model for the swimming of micro org

92 To do so, a computational fluid dynamics (CFD) model framework was established to

93 Here, we used a computational fluid dynamics (CFD) model of rat nasal cavity to simula

94 A computational fluid dynamics (CFD) model was used to investigate this

95 two-dimensional moving domain computational fluid dynamics (CFD) model, providing new insights into

96 I was used in conjunction with computational fluid dynamics (CFD) modeling to investigate the hemodyn

97 al tumor capillary models, and Computational Fluid Dynamics (CFD) modeling.

98 Computational fluid dynamics (CFD) simulation derived from the fusion

99 Computational fluid dynamics (CFD) simulation has emerged as a powerfu

100 lly expensive when integrating Computational Fluid Dynamics (CFD) simulation tools.

101 Furthermore, leveraging computational fluid dynamics (CFD) simulation, the method to predict t

102 Computational fluid dynamics (CFD) simulations employ assumptions abou

103 Computational Fluid Dynamics (CFD) simulations offer a means to detect

104 We performed computational fluid dynamics (CFD) simulations to calculate the wall s

105 We performed computational fluid dynamics (CFD) simulations to determine the variat

106 Here, we conducted image-based computational fluid dynamics (CFD) simulations to quantify the fluid m

107 Computational Fluid Dynamics (CFD) simulations were conducted to optim

108 Computaional fluid dynamics (CFD) simulations were performed to asses

109 Computational Fluid Dynamics (CFD) simulations were performed using th

110 re confirmed by fully resolved computational fluid dynamics (CFD) simulations.

111 changes between SS and OSS by computational fluid dynamics (CFD) simulations.

112 ularly significant, since most Computational Fluid Dynamics (CFD) studies to date have used monodispe

113 ned experimental protocols and computational fluid dynamics (CFD) studies.

114 In this paper, a computational fluid dynamics (CFD) study was conducted in a nondetermi

115 This paper uses Computational Fluid Dynamics (CFD) to conduct a parametric study to en

116 and electromyography and used computational fluid dynamics (CFD) to estimate the aerodynamic forces

117 ch pairing experimentation and computational fluid dynamics (CFD) was selected to provide comprehensi

118 nd WSS were quantified with 3D computational fluid dynamics (CFD).

119 er transurethral surgery using computational fluid dynamics (CFD).

120 M) and hemodynamic effects via computational fluid dynamics (CFD).

121 cted theoretical and experimental studies on fluid dynamic characteristics of laminar flows in wideni

122 n the cloudy atmosphere, and a computational fluid dynamics code for the Richtmyer-Meshkov instabilit

123 Fluid dynamics computations for tube-like geometries are

124 mediating platelet aggregation under varying fluid dynamic conditions, and modify the current interpr

125 When grown under intravascular-magnitude fluid dynamic conditions, K. pneumoniae spontaneously de

126 sperm response may be tuned to meet specific fluid-dynamic constraints, shear could act as a critical

127 Fluid dynamic design considerations are discussed, espec

128 To correlate intraoperative interface fluid dynamics during Descemet stripping automated endot

129 y capture technique-dependent differences in fluid dynamics during DSAEK.

130 suggest that neither polysaccharide altered fluid dynamics during infection since GXM behaved in sol

131 impure grain orientations because of complex fluid dynamics during solution coating.

132 pex myocardial perfusion gradient indicating fluid dynamic effects of diffuse coronary artery narrowi

133 anding how this adhesive bond can oppose the fluid dynamic effects of rapidly flowing blood to initia

134 ng applications beyond locomotion to include fluid dynamics, electronics, and environmental monitorin

135 scular endothelial cells in vivo occurs in a fluid dynamic environment due to blood flow, but the rol

136 These fluid dynamic events could be important to induce shear

137 ctoral-pelvic lateral fins that our computed fluid-dynamics experiments show passively generated lift

138 Using both experimental assays and fluid-dynamic finite element simulation models, we direc

139 improve approximations inside computational fluid dynamics for modeling two-dimensional turbulent fl

140 that the zebrafish LRO is more sensitive to fluid dynamics for symmetry breaking.

141 wever, there exists virtually no theoretical fluid-dynamic foundation to describe the influence of ex

142 iffusion equation in a quantum computational fluid dynamics framework.

143 Living systems rely on fluid dynamics from embryonic development to adulthood.

144 The laws of fluid dynamics govern vortex ring formation and precede

145 Computational fluid dynamic-guided design modifications successfully d

146 Computational fluid dynamics has demonstrated that abnormal KD coronar

147 capillary expansions, but the details of the fluid dynamics have not been elucidated.

148 Mathematical models including detailed fluid dynamics have previously been used to understand b

149 It was found that complex coupled fluid dynamics, heat transfer, and electrostatic phenome

150 ter technique, showing through computational fluid dynamics how the mixing efficiency strongly depend

151 We report the direct observation of fluid dynamics in a single zinc oxide nanotube with the

152 Deep breathing enhances cerebrospinal fluid dynamics in both groups, increasing displacement a

153 These observations hint at the polariton fluid dynamics in conditions of extreme intensities and

154 o our knowledge, this is the first time that fluid dynamics in diagnostic membranes have been analyze

155 undamental limitations imposed by Poiseuille fluid dynamics in flow cells, which we overcome using Co

156 aerosol viscosity and identify non-Newtonian fluid dynamics in model sea spray aerosol composed of Na

157 inked to X. fastidiosa biofilm formation and fluid dynamics in the functional foregut of sharpshooter

158 deprivation modulates cognitive, neural and fluid dynamics in the human brain.

159 The fluid dynamics in this regime are very different from th

160 grams challenge our current understanding of fluid dynamics in urination, jetting fluids like their l

161 erimental access to questions of microscopic fluid dynamics in vivo.

162 scuss concepts related to the development of fluid dynamics including flow, perivascular transport, d

163 , based on experiments, for the non-brittle, fluid dynamic induced fragmentation of low viscosity mel

164 These results also show that fluid dynamic interactions alone are sufficient to gener

165 by flexible medusan bell margins relies upon fluid dynamic interactions between entrained flows at th

166 al area according to minimal level of thermo-fluid-dynamic irreversibility.

167 ery low Reynolds number, the regime in which fluid dynamics is governed by Stokes equations, a helix

168 Computational fluid dynamics is used to determine the flow pattern wit

169 heric sulfate aerosols) from the Geophysical Fluid Dynamics Laboratory and Hadley Centre climate mode

170 Using the Geophysical Fluid Dynamics Laboratory comprehensive Earth System Mod

171 imate (A2 and B1 IPCC emissions; Geophysical Fluid Dynamics Laboratory General Circulation Models) on

172 e an earth system model from the Geophysical Fluid Dynamics Laboratory to investigate regional impact

173 Using computational fluid dynamics (Lattice Boltzmann Method) this work show

174 ns on filling and to assess whether impaired fluid dynamics may be a source of diastolic dysfunction.

175 rphologic data support the potential role of fluid dynamic mechanical factors in atherogenesis and ha

176 onerous task requiring specialized skills in fluid dynamics, mechanical design drafting, and manufact

177 unit and physical environment have uncovered fluid dynamic mechanisms of seed flight, protective meas

178 computed tomography to create computational fluid dynamics model cones.

179 elity, fully-coupled radiation transport and fluid dynamics model has been developed to quantify disi

180 The computational fluid dynamics model is used to determine the shape of a

181 We developed a computational fluid dynamics model of the ePBR, which predicted that i

182 dam environments, we combine a computational fluid dynamics model of the flow field at a dam and a be

183 perimental results are compared to a complex fluid dynamics model showing an agreement between the tw

184 ce an experimentally-validated physiological fluid dynamics model simulating inhaled onset of smallpo

185 Here we simulate stratocumulus clouds with a fluid dynamics model that includes detailed treatments o

186 We use a computational fluid dynamics model to show that this frequency-invaria

187 two-dimensional heterogeneous computational fluid dynamics model was developed and validated to stud

188 sed on full- and reduced-order computational fluid dynamic modeling, as well as artificial intelligen

189 three clades of excavates with computational fluid dynamic modeling, to understand the functional sig

190 intravascular ultrasound) and computational fluid dynamics modeling for WSS calculation.

191 Fluid dynamics modeling of an Ediacaran ecosystem illust

192 Computational fluid dynamics modeling was performed in 60 (30 extracar

193 Using immunohistochemistry, computational fluid dynamics modeling, and patch clamp recording, we d

194 uality monitoring campaign and computational fluid dynamic modelling (ENVI-met) were used to assess c

195 by trypan blue exclusion and flow cytometry; fluid dynamic modelling validates culture conditions.

196 crocapillary flow, verified by computational fluid dynamics modelling.

197 ctivation patterns by using 3D computational fluid dynamics models coupled to the motion of fish with

198 V reactors as well as validate computational fluid dynamics models that are widely used to simulate U

199 no-slip boundary typically used in standard fluid dynamics models.

200 behaviour relaxes the boundaries between the fluid dynamic niches of motile and non-motile phytoplank

201 r leak, extracorporeal membrane oxygenation, fluid dynamics of bronchopleural fistula airflow, and in

202 reconstruction techniques and computational fluid dynamics of coronary CT angiography (CCTA) data se

203 With increasing short-range attraction, the fluid dynamics of the cluster phase is arrested, leading

204 riments help to explain how dogs exploit the fluid dynamics of the generated column.

205 mage velocimetry validated the corresponding fluid dynamics of the numerical model.

206 maging, we probe directly the interconnected fluid dynamics of the vapour jet formed by the laser and

207 impact of plasma dynamics and plasma-driven fluid dynamics on the flame growth of laser ignited mixt

208 The multi-scale model incorporates cochlear fluid dynamics, organ of Corti (OoC) mechanics and outer

209 del of the cochlea that incorporates viscous fluid dynamics, organ of Corti microstructural mechanics

210 lytic framework established in computational fluid dynamics, our method is physiologically relevant,

211 may be sensitive to changes in intracranial fluid dynamic parameters such as cerebral perfusion pres

212 ose To identify volumetric and computational fluid dynamics parameters to predict AAAs that are likel

213 ribs on the porous surface of a cone) cause fluid dynamic phenomena distinct from current biological

214 Cerebrospinal fluid dynamics play a crucial role in maintaining brain

215 Computational fluid dynamics predicts that the corresponding drop in s

216 A physical understanding of this fluid-dynamic process is necessary for yielding the desi

217 ient-specific assessment using computational fluid dynamics provides an estimate of local hemodynamic

218 ed from theories of biochemical oscillation, fluid dynamics, reaction-diffusion-based pattern instabi

219 d systematically diverse animals use similar fluid dynamic relationships to generate swimming thrust.

220 Our results are important for studies in fluid dynamics, remote sensing, and polarimetry.

221 ulatures is key to modelling the contrasting fluid dynamic response between tumour samples.

222 icromotors, and along with the corresponding fluid dynamics, results in a highly efficient mobile CO2

223 Computational fluid dynamics serves a unique role in studying the hemo

224 Computational fluid dynamics simulated nasal airflow at steady inspira

225 esults suggest that pre-Fontan computational fluid dynamic simulation may be valuable for determining

226 Recently, fluid dynamic simulation models have identified distinct

227 ts of LPA stenosis motivated a computational fluid dynamic simulation study within 3-dimensional pati

228 A computational fluid dynamics simulation (CFD) was performed using our

229 the DropArray plate were quantified through fluid dynamics simulation and complete retention of susp

230 ows, validating the multiphase computational fluid dynamics simulation.

231 imensional image analysis, and computational fluid dynamics simulation.

232 lution advanced numerical CFD (computational fluid dynamics) simulation and rock-record examples, tha

233 Fluid dynamic simulations agree with observations from t

234 Using computational fluid dynamic simulations and in vivo thrombosis models,

235 Computational fluid dynamic simulations determined flow, velocity and

236 Computational fluid dynamic simulations of a basic monolithic structur

237 To address these two issues, computational fluid dynamic simulations of coupled dynamic two-phase f

238 ngle, which is consistent with computational fluid dynamic simulations showing that different angles

239 In this study, we use rigorous fluid dynamic simulations to provide a physical interpre

240 Steady computational fluid dynamic simulations were performed at baseline con

241 Computational fluid dynamic simulations were performed on seven lower

242 Detailed computational fluid dynamic simulations with multiphase flow models re

243 ict the behavior of a two-phase system using fluid dynamic simulations with water-butanol and water-c

244 sual flow behavior, and verify computational fluid dynamic simulations.

245 tion in the channel flow using computational fluid dynamics simulations and a previously developed mo

246 mensional models for automated computational fluid dynamics simulations and computed luminal shear st

247 ng procedure is proposed using computational fluid dynamics simulations and shape optimization to ass

248 Computational fluid dynamics simulations confirmed that adaptations in

249 Computational fluid dynamics simulations incorporating species diffusi

250 Computational fluid dynamics simulations of fibrous filters with 56 co

251 We used computational fluid dynamics simulations of low-altitude and near-wall

252 s and has been developed using computational fluid dynamics simulations of respiratory airflow and dr

253 ticle tracking velocimetry and computational fluid dynamics simulations to estimate the contractile f

254 Computational fluid dynamics simulations validate the efficacy of the

255 Computational fluid dynamics simulations were conducted in ANSYS Fluen

256 Computational fluid dynamics simulations were performed for various HX

257 Computational fluid dynamics simulations were performed to assess shea

258 Computational fluid dynamics simulations were used to investigate pati

259 l patterns can be predicted by computational fluid dynamics simulations with high experimental correl

260 Markov chain, verified against computational fluid dynamics simulations, indicate that the independen

261 h wind tunnel measurements and computational fluid dynamics simulations, we demonstrate aerodynamical

262 Combined with computational fluid dynamics simulations, we demonstrate that the LAPO

263 ts showing good agreement with computational fluid dynamics simulations.

264 spectroscopy velocimetry and finite element fluid dynamics simulations.

265 phenomena in multi-dimensional computational fluid dynamics simulations.

266 droplets may exhibit patterns resembling the fluid dynamics smaller airborne aerosols that follow the

267 dertaken using high-resolution computational fluid dynamic software.

268 Computational fluid dynamics software may be used to predict the influ

269 orresponding electrodynamic (Simion 8.1) and fluid dynamic (SolidWorks) simulations.

270 A commercial computational fluid dynamics solver was used to simulate peak systolic

271 rainment of metal micro-particles to similar fluid dynamic studies in other fields of science will be

272 A fungal individual can be viewed as a fluid, dynamic system that is characterized by hyphal ti

273 r, we coupled experimental and computational fluid dynamics techniques to: (i) accommodate glass eel

274 By investigating the fluid dynamics that controls the transport of the MVP in

275 work now supports an evolving model of body fluid dynamics that integrates exchangeable Na(+) stores

276 Intravessel variations were consistent with fluid dynamic theory.

277 As fluid dynamics throughout the placenta are driven by a v

278 Here we apply a fundamental technique from fluid dynamics to an ecosystem model to show how fronts

279 In parallel, we used simulations of fluid dynamics to analyze our experimental data.

280 ed favorably to an analytical model based on fluid dynamics to describe the energy deposition.

281 hree-dimensional modelling and computational fluid dynamics to establish the feeding mode of the enig

282 consider the vascular/interstitial/lymphatic fluid dynamics to show that tumors with larger lymphatic

283 Applying computational fluid dynamic tools based on accurate coronary physiolog

284 lli serve a mechanosensory function in which fluid dynamic torque is transmitted to the actin cytoske

285 ntum systems, which is suitable for encoding fluid dynamics transport phenomena within a lattice kine

286 Understanding fluid dynamics under extreme confinement, where device a

287 Finite element analysis and computational fluid dynamics was performed.

288 Computational fluid dynamics was used to model flow past multiple adhe

289 Computational fluid dynamics was used to simulate fluid flow inside fl

290 basis of flow measurements and computational fluid dynamics, we applied a tandem stenosis to the caro

291 iled three-dimensional analysis of the local fluid dynamics, we estimate a mean effective thickness o

292 Based on observations and theory of fluid dynamics, we propose that convection caused by bri

293 Using computational fluid dynamics, we show that osteostracan headshield mor

294 Computational fluid dynamics were applied to estimate the shear stress

295 a longstanding open question in mathematical fluid dynamics: whether smooth initial data for the 3D i

296 fully couples the Navier-Stokes equations of fluid dynamics with an actuated, elastic body model.

297 Navier-Stokes equations using computational fluid dynamics with overset grids, and validate our resu

298 By combining computational fluid dynamics with physical-chemical characteristics of

299 riment and prediction based on computational fluid dynamics, with experiment generally showing only s

300 derstanding and controlling complex unsteady fluid dynamics, with significant implications for engine