Skip to main navigation
Skip to search
Skip to main content
Ben-Gurion University Research Portal Home
Help & FAQ
Home
Profiles
Research output
Research units
Prizes
Press/Media
Student theses
Activities
Research Labs / Equipment
Datasets
Projects
Search by expertise, name or affiliation
Cracks in rubber
P. Trapper
, K. Y. Volokh
Research output
:
Contribution to journal
›
Article
›
peer-review
34
Scopus citations
Overview
Fingerprint
Fingerprint
Dive into the research topics of 'Cracks in rubber'. Together they form a unique fingerprint.
Sort by
Weight
Alphabetically
Keyphrases
Shear Modulus
100%
Rubber
100%
Failure Energy
100%
Brittle Materials
66%
Large Deformation
66%
Crack Propagation
66%
Mean Bond Energy
66%
Energy Limiters
66%
Soft Materials
66%
Griffith Theory
66%
Critical Tension
66%
Material Failure
33%
Hydrostatic Pressure
33%
Fracture Propagation
33%
Hyperelasticity
33%
Material Model
33%
Rubber-like
33%
Crack Initiation
33%
Constitutive Description
33%
Static Instability
33%
Strain Energy Density
33%
Crack Length
33%
Fracture Onset
33%
Structural Instability
33%
Linearized Elasticity
33%
Inverse Square Root
33%
Neo-Hookean Material Model
33%
Brittleness
33%
Engineering
Energy Engineering
100%
Limiters
37%
Shear Modulus
37%
Brittle Material
25%
Large Deformation
25%
Crack Propagation
25%
Material Model
25%
Soft Material
25%
Griffith Theory
25%
Square Root
12%
Applicability
12%
Initiation of Crack
12%
Strain Energy Density
12%
Critical Load
12%
Inverse Square
12%
Brittleness
12%
Fracture Propagation
12%
Crack Length
12%
Material Science
Elastic Moduli
100%
Brittleness
100%
Large Deformation
66%
Crack Propagation
66%
Elasticity
33%
Energy Density
33%
Thin Sheet
33%