Skip to main navigation
Skip to search
Skip to main content
Korea University Pure Home
Home
Profiles
Research units
Research output
Press/Media
Search by expertise, name or affiliation
Consistent energy-stable method for the hydrodynamics coupled PFC model
Junxiang Yang,
Junseok Kim
Research output
:
Contribution to journal
›
Article
›
peer-review
5
Citations (Scopus)
Overview
Fingerprint
Fingerprint
Dive into the research topics of 'Consistent energy-stable method for the hydrodynamics coupled PFC model'. Together they form a unique fingerprint.
Sort by
Weight
Alphabetically
Keyphrases
Energy Stability
100%
Energy Stable Methods
100%
PFC Model
100%
Crystallization
66%
Fluid Flow
66%
General Nonlinearity
66%
High Efficiency
33%
Phase Transition
33%
Shear Flow
33%
Numerical Experiments
33%
Total Mass
33%
Superior Performance
33%
Stability Accuracy
33%
Incompressible Fluid Flow
33%
Discrete Version
33%
Lagrange multiplier
33%
Energy Functional
33%
Stability Performance
33%
Simple Fluids
33%
Complex Fluids
33%
Ordering Time
33%
Fluid Dynamics
33%
Relaxation Method
33%
Colloidal Crystal
33%
Physical Phenomena
33%
Mathematical Equations
33%
Accuracy Performance
33%
Fully-decoupled
33%
Time-accurate
33%
Stable numerical Method
33%
Phase Field Crystal
33%
Incompressible NavierStokes Equations
33%
Energy Stable
33%
Fluid Systems
33%
L2-gradient Flow
33%
Discrete Method
33%
Mathematics
Time Step
100%
Nonlinearity
100%
Numerical Experiment
50%
Type Equation
50%
Energy Functional
50%
Phase Field
50%
Gradient Flow
50%
Total Mass
50%
Time Order
50%
Relaxation Method
50%
Mathematical Equation
50%
Elliptic Type
50%
Mathematical Method
50%
Lagrange Multiplier Method
50%
Engineering
Energy Engineering
100%
Hydrodynamics
100%
Coupled Fluid Flow
33%
Nonlinearity
33%
Incompressible Fluid
16%
Fluid Dynamics
16%
Shear Flow
16%
Numerical Experiment
16%
Fluid Flow
16%
Lagrange Multiplier Method
16%
Energy Functional
16%
Phase Field
16%
Complex Fluid
16%
Physical Phenomena
16%
Mathematical Equation
16%
Fluid System
16%
Discrete Method
16%
Chemical Engineering
Fluid Flow
100%