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Abstract

Several properties of the M-integral are clarified within the context of nonlinear elastic defect mechanics. A material damage expansion force vector associated with the integrand of the M-integral is derived by divergence vector operation of the Lagrangian energy density moment. It is concluded that the components of damage expansion force vector are indentified as the change of potential energy due to the self-similar expansion of one infinitesimal material element along the x₁ or x₂ direction. Subsequently, the physical interpretation of the M-integral over the contour enclosing all defects is explored in nonlinear elasticity containing multiple defects by an explicit analysis. The explicit analysis reveals that the M-integral is inherently related to the change of the total potential energy during the formation of defects from the initial non-damaged system in addition to the nonlinear strain energy within the area enclosed by integration contour.

Keywords

M-integral material damage expansion force physical interpretation nonlinear elasticity defect mechanics

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References

Budiansky

Rice

(1973) Conservation laws and energy release rates. ASME Journal of Applied Mechanics 40: 201–203.

Carka

Landis

(2011) On the path-dependence of the J-integral near a stationary crack in an elastic-plastic material. ASME Journal of Applied Mechanics. 78: 011006.

Chang

Chien

(2002) Evaluation of M-integral for anisotropic elastic media with multiple defects. International Journal of Fracture 114(3): 267–289.

Chang

Peng

(2004) Use of M integral for rubbery material problems containing multiple defects. ASCE Journal of Engineering Mechanics 130(5): 589–598.

Chen

(2001a) M-integral analysis for two-dimensional solids with strongly interacting microcracks. Part I: in an infinite brittle solid. International Journal of Solids and Structures 38(18): 3193–3212.

Chen

(2001b) M-integral analysis for two-dimensional solids with strongly interacting microcracks. Part II: in the brittle phase of an infinite metal/ceramic bimaterial. International Journal of Solids and Structures 38(18): 3213–3232.

Eischen

Herrmann

(1987) Energy release rates and related balance laws in linear elastic defect mechanics. ASME Journal of Applied Mechanics 54(2): 388–392.

Eshelby

(1951) The force on an elastic singularity. Philosophical Transactions of the Royal Society A 244(877): 87–112.

Eshelby

(1975) The elastic energy-momentum tensor. Journal of Elasticity 5(3–4): 321–335.

10.

Kienzler

Herrmann

(1997) On the properties of the Eshelly tensor. Acta Mechanica 125(1–4): 73–91.

11.

King

Herrmann

(1981) Nondestructive evaluation of the J and M integrals. ASME Journal of Applied Mechanics 48(1): 83–87.

12.

Knowles

Stermberg

(1972) On a class of conservation laws in linearized and finite elastostatics. Archive for Rational Mechanics and Analysis 44(3): 187–211.

13.

Chen

Liu

(2001) On the relation between the M-integral and the change of the total potential energy in damaged brittle solids. Acta Mechanica 150(1–2): 79–85.

14.

McMeeking

(1977) Finite deformation analysis of crack-tip opening in elastic-plastic materials and implications for fracture. Journal of the Mechanics and Physics of Solids 25(5): 357–381.

15.

Noether

(1971) Invariant variational problems. Transport Theory and Statistical Physics 1(3): 183–207.

16.

Ramberg W and Osgood WR (1943) Description of Stress-Strain Curves by Three Parameters. Technical Note No. 902. Washington, DC: National Advisory Committee for Aeronautics.

17.

Rice

(1986) A path independent integral and the approximate analysis of strain concentration by notches and cracks. ASME Journal of Applied Mechanics 35(2): 379–386.

On the physical interpretation of the M-integral in nonlinear elastic defect mechanics

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