TY - RPRT
T1 - Existence for elastodynamic Griffith fracture with a weak maximal dissipation condition
Y1 - 2018
A1 - Gianni Dal Maso
A1 - Cristopher J. Larsen
A1 - Rodica Toader
AB - We consider a model of elastodynamics with fracture evolution, based on energy-dissipation balance and a maximal dissipation condition. We prove an existence result in the case of planar elasticity with a free crack path, where the maximal dissipation condition is satisfied among suitably regular competitor cracks.
UR - http://preprints.sissa.it/handle/1963/35308
U1 - 35616
U2 - Mathematics
U4 - 1
U5 - MAT/05
ER -
TY - RPRT
T1 - Existence for constrained dynamic Griffith fracture with a weak maximal dissipation condition
Y1 - 2015
A1 - Gianni Dal Maso
A1 - Cristopher J. Larsen
A1 - Rodica Toader
AB - There are very few existence results for fracture evolution, outside of globally minimizing quasi-static evolutions. Dynamic evolutions are particularly problematic, due to the difficulty of showing energy balance, as well as of showing that solutions obey a maximal dissipation condition, or some similar condition that prevents stationary cracks from always being solutions. Here we introduce a new weak maximal dissipation condition and show that it is compatible with cracks constrained to grow smoothly on a smooth curve. In particular, we show existence of dynamic fracture evolutions satisfying this maximal dissipation condition, subject to the above smoothness constraints, and exhibit explicit examples to show that this maximal dissipation principle can indeed rule out stationary cracks as solutions.
UR - http://urania.sissa.it/xmlui/handle/1963/35045
U1 - 35277
U2 - Mathematics
U4 - 1
U5 - MAT/05
ER -
TY - JOUR
T1 - Energy release rate and stress intensity factor in antiplane elasticity
JF - Journal de Mathematiques Pures et Appliquees 95 (2011) 565-584
Y1 - 2011
A1 - Giuliano Lazzaroni
A1 - Rodica Toader
AB - In the setting of antiplane linearized elasticity, we show the existence of the stress intensity factor and its relation with the energy release rate when the crack path is a C1,1 curve. Finally, we show that the energy release rate is continuous with respect to the Hausdorff convergence in a class of admissible cracks.
PB - Elsevier
UR - http://hdl.handle.net/1963/3780
U1 - 546
U2 - Mathematics
U3 - Functional Analysis and Applications
ER -