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Equine hoof wall: Structure, properties, and bioinspired designs
Benjamin S. Lazarus
, Rachel K. Luu
, Samuel Ruiz-Pérez
, Wendell Bruno Almeida Bezerra
, Kevin Becerra-Santamaria
, Victor Leung
, Victor Hugo Lopez Durazo
,
Iwona Jasiuk
, Josiane D.V. Barbosa
, Marc A. Meyers
Mechanical Science and Engineering
Biomedical and Translational Sciences
Bioengineering
Aerospace Engineering
National Center for Supercomputing Applications (NCSA)
Beckman Institute for Advanced Science and Technology
Carl R. Woese Institute for Genomic Biology
Civil and Environmental Engineering
Center for the Study of Global Gender Equity
Research output
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Keyphrases
Structure-property Relationships
100%
Wall Structure
100%
Structure Design
100%
Bio-inspired Design
100%
Hoof Wall
100%
Equine Hoof
100%
Impact Energy
27%
Horse Hoof
27%
Fracture Control
27%
Lamellae
18%
Energy Absorption
18%
Dynamic Loading
18%
Impact Resistance
18%
Drop Tower Test
18%
Hierarchical Structure
9%
Microstructure
9%
Gradient Structure
9%
Biological Materials
9%
Additive Manufacturing
9%
Reinforced
9%
Tubular Structure
9%
Structural Characterization
9%
Multi-material
9%
Creep Test
9%
Strain Rate
9%
Meso
9%
Mechanical Properties
9%
Loading Conditions
9%
Characteristic Relaxation Time
9%
Compact Tension
9%
Viscoelastic Response
9%
Failure Mechanism
9%
Fractography
9%
Nanoscale Features
9%
Viscoelasticity
9%
Design Basis
9%
Toughness
9%
Material Response
9%
Quasi-static Loading
9%
Internal Stress
9%
Response-adapted
9%
Property Relations
9%
Maxwell
9%
Hoof
9%
Dynamic Load
9%
Low Impact
9%
Stiffness Variation
9%
Resistance Control
9%
Mesoscale Features
9%
Control Properties
9%
Broken Fibers
9%
Relaxation Test
9%
Bio-inspired Structure
9%
Near-natural
9%
Print Design
9%
Bioinspiration
9%
Keratin Biomaterials
9%
Absorption Control
9%
Impact Fracture
9%
Hoof Keratin
9%
Hydration Gradient
9%
Impact Mode
9%
Engineered Design
9%
Spatial Stiffness
9%
Natural Fiber Composites
9%
Engineering
Dynamic Loads
100%
Impact Energy
100%
Energy Absorption
66%
Tower
66%
Nanoscale
33%
Fiber-Reinforced Composite
33%
Creep
33%
Mesoscale
33%
Strain Rate
33%
Loading Condition
33%
Control Sample
33%
Fractography
33%
Failure Mechanism
33%
Material Response
33%
Internal Stress
33%
Property Relationship
33%
Natural Fibre
33%
Broken Fiber
33%
Control Property
33%
Relaxation Time
33%
Viscoelasticity
33%
Impact Resistance
33%
Material Science
Dynamic Loads
100%
Fiber-Reinforced Composite
33%
Biomaterial
33%
Creep
33%
Strain Rate
33%
Fractography
33%
Surface (Surface Science)
33%
Viscoelasticity
33%
Impact Resistance
33%
Natural Fiber
33%
Keratin
33%