Engineering
Finite Element Method
100%
Finite Element Modeling
50%
Multiscale
30%
Young's Modulus
19%
Microstructure
18%
Constitutive Model
16%
Peridynamics
15%
High Resolution
13%
High Performance Fiber
13%
Fiber-Reinforced Concrete
13%
Microscale
13%
Load Case
11%
Computational Cost
11%
Mesoscale
11%
Fluid-Structure Interaction
11%
Random Field
10%
Surrogate Model
10%
Finite Element Mesh
10%
Nuclear Reactor
9%
Finite Element Simulation
9%
Transients
9%
Virtual Reality
8%
Tensile Testing
8%
Material Behavior
8%
Simulators
8%
Transmissions
8%
Running Speed
8%
Plastic Deformation
8%
Macroscale
8%
Progression
8%
Experimental Result
8%
Internals
8%
Tendon Tissue
7%
Solid Mechanics
7%
Element Method
6%
Joints (Structural Components)
6%
Local Approach
6%
Polycrystalline
6%
Temperature Distribution
6%
Engineering Application
6%
Neutronics
6%
Computer Aided Design
6%
Fusion Power
6%
Computational Fluid Dynamics
6%
Implant
6%
Nonlinearity
5%
Material Nonlinearity
5%
Degree of Freedom
5%
Micromechanics
5%
Steel Fiber
5%
Material Science
Finite Element Modeling
44%
Materials Property
33%
Tomography
22%
X-Ray Computed Tomography
15%
Elastic Moduli
14%
Tensile Testing
14%
Young's Modulus
13%
Carbon Fiber
13%
Thermal Conductivity
13%
Fiber Reinforced Concrete
13%
Stress Analysis
13%
Homogenization
13%
Density
11%
X-Ray Microtomography
11%
Elastic Property
10%
Thermal Expansion
9%
Computational Fluid Dynamics
8%
Elasticity
8%
Heterogeneous Material
8%
Tungsten
8%
Solidification
8%
Microstructure
8%
Stochastic Modeling
6%
Fluid-Structure Interaction
6%
Thermal Stress
6%
Debonding
5%
Fibroblast
5%
Micromechanics
5%
Thermal Analysis
5%