Engineering
Lattice-Boltzmann Method
100%
Particle Reynolds Number
100%
Shear Thickening
100%
Rheology
100%
Shear Rate
66%
Apparent Viscosity
66%
Solid Fraction
33%
Spring Force
33%
Reynolds' Number
33%
Newtonian Liquid
33%
High Viscosity
33%
No-Slip Boundary Condition
33%
Short Range
33%
Good Agreement
33%
Empirical Equation
33%
Scale Distance
33%
History Effect
33%
Spherical Particle
33%
Clustering
33%
Surface
33%
Cluster Formation
33%
High Reynolds Number
33%
Hysteresis Effect
33%
Fluid Viscosity
33%
Simple Shear Flow
33%
Sudden Change
33%
Experimental Measurement
33%
Particle Concentration
33%
Direct Numerical Simulation
33%
INIS
suspensions
100%
inertia
100%
rheology
100%
particles
100%
shear
100%
reynolds number
45%
viscosity
36%
rotation
27%
volume
18%
solids
18%
increasing
9%
surfaces
9%
distance
9%
simulation
9%
range
9%
hysteresis
9%
slip
9%
springs
9%
boundary conditions
9%
liquids
9%
equations
9%
grids
9%
concentration
9%
computerized simulation
9%
interstitials
9%
Earth and Planetary Sciences
Particles
100%
Rheology
100%
Thickening
100%
History
100%
Reynolds Number
36%
Whirl
27%
Fraction
27%
Solid
18%
Rate
18%
Boundary Condition
9%
Agreement
9%
High Reynolds Number
9%
Increasing
9%
Shear Flow
9%
Clustering
9%
Liquid
9%
Distance
9%
Keyphrases
Shear History
100%
Finite Inertia
100%
Immersed Boundary-lattice Boltzmann Method
100%
Particle Clustering
66%
Particle Cluster
33%
Thickening Fraction
33%