The J-integral represents a way to calculate the strain energy release rate, or work (energy) per unit fracture surface area, in a material.[1] The theoretical concept of J-integral was developed in 1967 by G. P. Cherepanov[2] and independently in 1968 by James R. Rice,[3] who showed that an energetic contour path integral (called J) was independent of the path around a crack.
Experimental methods were developed using the integral that allowed the measurement of critical fracture properties in sample sizes that are too small for Linear Elastic Fracture Mechanics (LEFM) to be valid.[4] These experiments allow the determination of fracture toughness from the critical value of fracture energy JIc, which defines the point at which large-scale plastic yielding during propagation takes place under mode I loading.[5]
The J-integral is equal to the strain energy release rate for a crack in a body subjected to monotonic loading.[6] This is generally true, under quasistatic conditions, only for linear elastic materials. For materials that experience small-scale yielding at the crack tip, J can be used to compute the energy release rate under special circumstances such as monotonic loading in mode III (antiplane shear). The strain energy release rate can also be computed from J for pure power-law hardening plastic materials that undergo small-scale yielding at the crack tip.
The quantity J is not path-independent for monotonic mode I and mode II loading of elastic-plastic materials, so only a contour very close to the crack tip gives the energy release rate. Also, Rice showed that J is path-independent in plastic materials when there is no non-proportional loading. Unloading is a special case of this, but non-proportional plastic loading also invalidates the path-independence. Such non-proportional loading is the reason for the path-dependence for the in-plane loading modes on elastic-plastic materials.
The two-dimensional J-integral was originally defined as (see Figure 1 for an illustration)
J:=\int\Gamma\left(W~dx2-t ⋅ \cfrac{\partialu
W=
| [\varepsilon] | |
| \int | |
| 0 |
[\boldsymbol{\sigma}]:d[\boldsymbol{\varepsilon}]~;~~[\boldsymbol{\varepsilon}]=\tfrac{1}{2}\left[\boldsymbol{\nabla}u+(\boldsymbol{\nabla}u)T\right]~.
Ji:=\lim\varepsilon →
| \int | |
| \Gamma\varepsilon |
\left(W(\Gamma)ni-nj\sigmajk~\cfrac{\partialuk(\Gamma,xi)}{\partialxi}\right)d\Gamma
Ji
xi
\varepsilon
\Gamma
Rice also showed that the value of the J-integral represents the energy release rate for planar crack growth.The J-integral was developed because of the difficulties involved in computing the stress close to a crack in a nonlinear elastic or elastic-plastic material. Rice showed that if monotonic loading was assumed (without any plastic unloading) then the J-integral could be used to compute the energy release rate of plastic materials too.
For isotropic, perfectly brittle, linear elastic materials, the J-integral can be directly related to the fracture toughness if the crack extends straight ahead with respect to its original orientation.
For plane strain, under Mode I loading conditions, this relation is
J\rm=G\rm=
| 2 | ||
| K | \left( | |
| \rmIc |
| 1-\nu2 | |
| E |
\right)
G\rm
K\rm
\nu
For Mode II loading, the relation between the J-integral and the mode II fracture toughness (
K\rm
J\rm=G\rm=
| 2 | ||
| K | \left[ | |
| \rmIIc |
| 1-\nu2 | |
| E |
\right]
For Mode III loading, the relation is
J\rm=G\rm=
| 2 | ||
| K | \left( | |
| \rmIIIc |
| 1+\nu | |
| E |
\right)
Hutchinson, Rice and Rosengren subsequently showed that J characterizes the singular stress and strain fields at the tip of a crack in nonlinear (power law hardening) elastic-plastic materials where the size of the plastic zone is small compared with the crack length. Hutchinson used a material constitutive law of the form suggested by W. Ramberg and W. Osgood:
| \varepsilon | = | |
| \varepsilony |
| \sigma | +\alpha\left( | |
| \sigmay |
| \sigma | |
| \sigmay |
\right)n
If a far-field tensile stress σfar is applied to the body shown in the adjacent figure, the J-integral around the path Γ1 (chosen to be completely inside the elastic zone) is given by
| J | |
| \Gamma1 |
=\pi(\sigmafar)2.
| J | |
| \Gamma1 |
=
| -J | |
| \Gamma2 |
.
| J | |
| \Gamma2 |
=-\alphaKn+1r(n+1)(s-2)+1I
s=
| 2n+1 | |
| n+1 |
K=\left(
| \beta\pi | |
| \alphaI |
| ||||
| \right) |
(\sigmafar
| ||||
| ) |
The asymptotic expansion of the stress field and the above ideas can be used to determine the stress and strain fields in terms of the J-integral:
\sigmaij=\sigmay\left(
| EJ | ||||||||
|
\right){1\over{n+1}}\tilde{\sigma}ij(n,\theta)
\varepsilonij=
| \alpha\varepsilony | |
| E |
\left(
| EJ | ||||||||
|
\right){n\over{n+1}}\tilde{\varepsilon}ij(n,\theta)
\tilde{\sigma}ij
\tilde{\varepsilon}ij
These expressions indicate that J can be interpreted as a plastic analog to the stress intensity factor (K) that is used in linear elastic fracture mechanics, i.e., we can use a criterion such as J > JIc as a crack growth criterion.