Title: Chapter 2: Elasticity and Plasticity
1Chapter 2Elasticity and Plasticity
2Tensile Strength Testing Machine
3Elasticity
Stressstrain curves in an elastic regime. (a)
Typical curve for metals and ceramics. (b)
Typical curve for rubber.
4Strain Energy Density
5Shear Stress and Strain
(a) Specimen subjected to shear force. (b) Strain
undergone by small cube in shearregion. (c)
Specimen (cylinder)subjected to torsion by a
torque T.
6Poissons Ratio
In an isotropic material, e11 is equal to e22.
(a) Unit cube being extended in direction Ox3.
(b) Unit cube in body subjected to tridimensional
stress only stresses on the three exposed faces
of the cube are shown.
7More Complex State of Stresses
8Mohr Circle
(a) Biaxial (or bidimensional) state of stress.
(b) Mohr circle and construction of general
orientation 0X1 X2 (c) Mohr circle and
construction of principal stresses and
maximum shear stresses (Method I).
9Mohr Circle
10Pure Shear
11Anisotropic Effects
12Elastic Modulus
13Elastic Compliance and Stiffness Matrix
14Anisotropy of Cubic System
Zeners anisotropy ratio
Youngs modulus
Shear modulus
Bulk modulus
Poissons ratio
Lame constants
15Youngs Modulus and Shear Modulus of
Monocrystalline Cu
16Youngs Modulus and Shear Modulus Monocrystalline
Zirconia
17Tridimensional Polar Plot for Zirconium
18Polycrystal
Voigt average assume strain is same everywhere
Reuss average assume stress is same everywhere
19Porosity on Youngs Modulus
Watchman and Mackenzie
20Microcracks vs. Youngs Modulus
21Microcracks vs. Youngs Modulus (contd)
1973 Salganik model
1974 Oconnel Budiansky model
22Elastic Properties of Polymers
23Viscoelasticity
n0 plastic n1 linear viscous (Newtonian) n
power law
Viscosity coefficient
Fluidity
24Viscoelasticity (contd)
Tensile storage modulus
Tensile loss modulus
25Rubber Elasticity
From thermodynamics, one can derive
Extension ratio
26Elastic Properties of Biological Materials
(a) Stressstrain response of human vena cava
circles-loading squares-unloading. (Adapted from
Y. C. Fung, Biomechanics (New York Springer,
1993),p. 366.) (b) Representation of mechanical
response in terms of tangent modulus (slope of
stressstrain curve) vs. stress. (Adapted from Y.
C. Fung. Biomechanics, New York Springer,1993),
p. 329.)
27Blood Vessels Dimensions
28Residual Stresses in Arteries
29Cartilage Fiber Network
30Mesostructure of Cartilage
(a) Mesostructure of cartilage (consisting of
four zones) showing differences in structure as a
function of distance from surface the bone
attachment is at bottom. (From G. L. Lucas, F. W.
Cooke, and E. A. Friis, A Primer on Biomechanics
(New York Springer, 1999), p. 273.) (b)
Cross-section of human cartilage showing regions
drawn schematically in (a). (Courtesy of K. D.
Jadin and R. I. Shah.)
31Mechanical Behavior of Superficial Zone of
Cartilage
Stressstrain curve for samples from the
superficial zone of articular cartilage. Samples
were cut parallel and perpendicular to collagen
fiber orientation. (From G. E. Kempson,
Mechanical Properties of Articular Cartilage. In
Adult Articular Cartilage, ed. M. A. R. Freeman
(London Sir Isaac Pitman and Sons Ltd., 1973),
pp. 171228.)
32Mechanical Properties of a DNA
33Stretching Force vs. Relative Extension for a DNA
Molecule
34Stresses Acting on a Thin Film
Effect of stresses acting on thin film on bending
of substrate (a) tensile stresses in thin film
(b) compressive stresses in thin film.
35Elastic Constant and Bonding
Two atoms with an imaginary spring between them
(a) equilibrium position (b) stretched
configuration under tensile force (c) compressed
configuration under compressive force.
36Attraction and Repulsion Between Two Atoms
(a) Interaction energies (attractive and
repulsive terms) as a function of separation (b)
Force between two atoms as a function of
separation notice decrease in slope as
separation increases.