Engineering
Micromechanics
100%
Interfacial Imperfection
53%
Finite Element Analysis
48%
Effective Property
47%
Computer Simulation
47%
Piezoelectric
41%
Interfacial Damage
33%
Face-Centered Cubic
32%
Mechanical Response
32%
Applicability
27%
Anisotropic Matrix
27%
Interfacial Thermal Resistance
27%
Effective Thermal Conductivity
27%
Nanocomposite
27%
Atomistic Simulation
27%
Plastic Deformation
27%
Beam Element
27%
Simulation Result
20%
Energy Harvesting
19%
Nanometre
18%
Loading Condition
18%
Thermoelectricity
18%
Porosity
18%
Interfacial Resistance
17%
Diamond
17%
Ray Diffraction
17%
Deep Learning Method
17%
Graphene
16%
Multiscale Modeling
16%
Length Scale
16%
2D Material
16%
Nanoparticle
14%
Harvester
13%
Imperfect Interface
13%
Optimised Design
13%
Induced Stress
13%
Centered Cubic Metal
13%
Self-Powered
13%
Stacking Fault Energy
13%
Machine Learning Algorithm
13%
Phase Separation
13%
Polymer Matrix
13%
Wave Energy
13%
Closed Form Solution
13%
Crack Growth
13%
Impact Damage
13%
Indentation
13%
Dislocation Dynamics
13%
Damage Mechanism
13%
Impact Response
13%
Material Science
Micromechanics
86%
Homogenization
84%
Nanowire
55%
Graphene
44%
Mechanical Metamaterials
41%
Nanocomposite
41%
Nucleation
34%
Plastic Deformation
33%
Piezoelectricity
32%
Crystal Structure
27%
Thermoelectrics
27%
X-Ray Diffraction
27%
Diamond
27%
Heat Resistance
20%
Thermal Conductivity
20%
Crystal Defect
20%
Particle Reinforced Composites
18%
Elastic Moduli
17%
Metamaterial
17%
Two-Dimensional Material
16%
Nanoparticle
16%
Crystal Structure
16%
Anisotropy
15%
Wettability
13%
Lithography
13%
Elastomer
13%
Nacre
13%
Polymer Matrix
13%
Silver
13%
Mechanical Failure
13%
Indentation
13%
Crack Growth
13%
Tape
13%
Cellular Structure
13%
Transmission Electron Microscopy
13%
Volume Fraction
13%
Stress Concentration
12%
Density
12%
Stress Field
10%
Percolation
8%
Mechanical Stability
7%
Transistor
6%
Three Dimensional Printing
6%
Crack Formation
5%
