Skip to main navigation
Skip to search
Skip to main content
PolyU Scholars Hub Home
Help & FAQ
Link opens in a new tab
Search content at PolyU Scholars Hub
Home
Researchers
Units
Research output
Prizes
Activities
Press/Media
Student theses
Flaw tolerant bulk and surface nanostructures of biological systems.
Huajian Gao
, Baohua Ji
, Markus J. Buehler
,
Haimin Yao
Research output
:
Journal article publication
›
Journal article
›
Academic research
›
peer-review
86
Link opens in a new tab
Citations (Scopus)
Overview
Fingerprint
Fingerprint
Dive into the research topics of 'Flaw tolerant bulk and surface nanostructures of biological systems.'. Together they form a unique fingerprint.
Sort by
Weight
Alphabetically
Keyphrases
Fracture Energy
100%
Effective Stress
100%
Surface Microstructure
100%
Biological Systems
100%
Gecko
100%
Sacrificial Bonds
100%
Bulk Nanostructures
100%
Slippery Liquid-Infused Porous Surfaces (SLIPS)
100%
Platelets
66%
Nanometer Scale
66%
Bone-like
66%
Spatulas
66%
Flaw Tolerance
66%
Ca++
66%
Strength Optimization
66%
Protein-mineral Interactions
66%
Entropic Elasticity
66%
Crosslinking Methods
66%
Energy Absorption
33%
Adhesion
33%
Stiffness
33%
Bioengineering
33%
Energy Dissipation
33%
Shear Stress
33%
System Strength
33%
Large Aspect Ratio
33%
Stress Level
33%
Structural Connectivity
33%
Fracture Strength
33%
Effective Strain
33%
Adhesion Strength
33%
Shear Tension
33%
Bonding Mechanism
33%
Low Modulus
33%
Crystallite Size
33%
Superior Mechanical Properties
33%
Biological Materials
33%
Crack-like Flaw
33%
Chain Model
33%
Atomistic Simulation
33%
Biopolymers
33%
Hierarchical Level
33%
Theoretical Strength
33%
Characteristic Dimensions
33%
Protein Domain
33%
Structure Component
33%
Animal Species
33%
Gecko Adhesion
33%
Metal Plasticity
33%
Continuum Modeling
33%
Mineral Crystals
33%
Critical Shear Strain
33%
Hierarchical Surface
33%
Adhesion Energy
33%
Mineral Nanoparticles
33%
Low Toughness
33%
Nanoprotrusion
33%
Hierarchical Composites
33%
Simple Tension
33%
Effective Shear Stress
33%
Model Simulation
33%
Protein Composites
33%
Engineering
Nanomaterial
100%
Biological System
100%
Nanoscale
100%
Effective Stress
100%
Fracture Energy
100%
Nanometre
66%
Biocomposite
66%
Platelet
66%
Fits and Tolerances
66%
Entropic Elasticity
66%
Model Chain
33%
Critical Role
33%
Structure Surface
33%
Energy Dissipation
33%
Stress Level
33%
Effective Strain
33%
Crystal Size
33%
Bond Mechanism
33%
Composite Structure
33%
Nanoparticles
33%
Theoretical Strength
33%
Atomistic Simulation
33%
Shear Strain
33%
Aspect Ratio
33%
Energy Absorption
33%
Fracture Strength
33%
Biopolymer
33%
Material Science
Nanostructure
100%
Surface (Surface Science)
100%
Composite Material
66%
Biocomposites
66%
Elasticity
66%
Platelet
66%
Nanoparticle
33%
Fracture Toughness
33%
Biomaterial
33%
Surface Structure
33%
Bond Strength (Materials)
33%
Shear Strain
33%
Biopolymer
33%
Protein Domain
33%
Chemical Engineering
Nanostructure
100%
Nanoparticle
33%