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Research overview:
Our research focuses on understanding multiphysics nonlinear behaviors, such as fracture and damage, in advanced materials through numerical simulations and multiscale modeling. By integrating local and nonlocal methods, we aim to capture complex deformation and crack evolution in mechanical metamaterials and composites across multiple length scales.
These studies enable us to design and predict the mechanical properties of materials, bridging microstructural features with macroscopic mechanical performance for next-generation smart and resilient materials.
Research topics span:
고체 및 전산 역학 (Solid & Computational Mechanics)
파괴 역학 (Fracture Mechanics)
페리다이나믹스 (Peridynamics)
생체모사 복합재료 (Bio-inspired Composites)
기계적 메타물질 (Mechanical Metamaterials)
#Computational mechanics, #Fracture, #Impact, #Composites, #3D printing, #Biomimetics
#전산역학, #파괴, #충돌, #복합재료, #3D 프린팅, #자연모사
Current Research topics of interest:
Crack-controllable materials
Adaptive numerical modeling for fracture simulation
Irregular-patterned metamaterials
#MD (nano-scale)
#MD (nano-scale)
#Fracture
#Fracture
#Mechanical properties
#Mechanical properties
#페리다이나믹스 (Micro-macro-scale)
#페리다이나믹스 (Micro-macro-scale)
#Coupling
#Coupling
#Fracture
#Fracture
#FEM (Macro-scale)
#FEM (Macro-scale)
#Composite
#Composite
#Biomimetics
#Biomimetics
#Impact
#Impact
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