Crack-: Working Model 2d

[ \Delta W = \int_\Gamma_N \mathbft\cdot \Delta\mathbfu,\mathrmdS . \tag7 ]

Elements with (\eta_e > \eta_\texttol) are refined (bisected) and coarsening is applied where (\eta_e < 0.1,\eta_\texttol). This strategy concentrates degrees of freedom only where the crack evolves, keeping the global problem size modest. A monolithic coupling (solving (\mathbfu) and (\phi) simultaneously) is possible but computationally expensive. Instead, we adopt the staggered scheme (Miehe et al., 2010) that is unconditionally stable for quasi‑static loading: Working Model 2d Crack-

The regularisation length (\ell) controls the width of the diffusive crack zone ((\approx 3\ell)). When (\ell\to0), (\Pi) (\Gamma)-converges to the classical Griffith functional. Stationarity of (\Pi) with respect to admissible variations (\delta\mathbfu) and (\delta\phi) yields the coupled Euler‑Lagrange equations : Stationarity of (\Pi) with respect to admissible variations

where (N_n) is the number of nodes. Quadratic interpolation is essential to resolve the steep gradients of (\phi) within the diffusive crack zone. A goal‑oriented error estimator based on the phase‑field gradient is used: keeping the global problem size modest.