true stress (σt true stress is the stress determined by...

True Stress (σT)True stress is the stress determined by the instantaneous load acting on the

instantaneous cross-sectional areaTrue stress is related to engineering stress:Assuming material volume remains constant

AA

AP

AA

AP

AP o

oo

oT ** ===σ

ll AA oo =

)1(1 ε+=+δ

=+δ

==oo

o

o

o

AA

ll

l

l

l )1()1( ε+σ=ε+=σo

T AP

True Strain (εT)The rate of instantaneous increase in the instantaneous gauge length.

)ln(

lnln

ln

εε

ε

ε

+=

∆+⇒

∆+=

== ∫

1T

oo

o

o

oT

oT

d

l

l

l

l

l

ll

l

l

l

l

Strain Hardening Parameter (n)

Strain hardening parameter

0<n<1T

T

T

T

dd

nεσ

εσ

=

nTT Kεσ =

True Stress-Strain Curve

)ln( ; o

Ti

T ll

AF

== εσ

o

o

o lll

AF −

== εσ ;

Instability in TensionNecking or localized deformation begins at maximum load, where the increase in stress due to decrease in the cross-sectional area of the specimen becomes greater than the increase in the load-carrying ability of the metal due to strain hardening. This conditions of instability leading to localized deformation is defined by the condition δP = 0.

T

T

AA

σδσδ

=−0=+= TT AAP δσδσδAP Tσ=

From the constancy-of-volume relationship,

TAA

ll δεδδ

=−=iioo lAlAV ==

so that at the point of tensile instability

T

TnT

T

TnTT nKnK

εσ

εδεδσ

εσ === −1 TT

T σδεδσ

= But

Instability occurs when ε = n

The necking criterion can be expressed more explicitly if engineering strain is used. ( ) T

O

o

TT

T

LL

LLLL

σεδεδσ

δεδσ

δδ

δεδσ

δεδε

δεδσ

δεδσ

=+=

=== 1

//

εδεδ

+=

1Tσσ

1+ε

σT

ε1

Fracture BehaviorDuctile material – Significant plastic deformation and energy absorption (toughness) before fracture.

Characteristic feature of ductile material - necking

Brittle material – Little plastic deformation or energy absorption before fracture.

Characteristic feature of brittle materials – fracture surface perpendicular to the stress.

Steel

Before and after fracture

Ductile Fracture (Dislocation Mediated): Extensive plastic deformation. Necking, formation of small cavities, enlargement of cavities, formation of cup-and-cone. Typical fibrous structure with “dimples”.

(a) Necking, (b) Cavity Formation, (c) Cavity coalescence to form a

crack, (d) Crack propagation,(e) Fracture

Crack grows 90o to applied stress

45O - maximum shear stress

Scanning Electron Microscopy: Fractographic studies at high resolution. Spherical “dimples” correspond to micro-cavities that initiate crack formation.

Brittle Fracture (Limited Dislocation Mobility): very little deformation, rapid crack propagation. Direction of crack propagation perpendicular to applied load. Crack often propagates by cleavage - breaking of atomic bonds along specific crystallographic planes (cleavage planes).

Brittle fracture in a mild steel

Intergranular fracture: Crack propagation is along grain boundaries (grain boundaries are weakened or embrittledby impurities segregation etc.)

Transgranular fracture: Cracks pass through grains. Fracture surface has faceted texture because of different orientation of cleavage planes in grains.

Stress-Strain Behavior of CeramicsFlexural Strength: the stress at fracture under the bending tests. It’s

also called Modulus of rupture, fracture strength, or the bend strength

3-point Bending tests

3

223

RLFbdLF

ffs

ffs

πσ

σ

=

=

BrittleDuctile