Quasi-Brittle Fracture: The Blended Approach (2503.20109v2)

Abstract: A field theory is presented for predicting damage and fracture in quasi-brittle materials. The approach taken here is new and blends a non-local constitutive law with a two-point phase field. In this formulation, the material displacement field is uniquely determined by the initial boundary value problem. The theory naturally satisfies energy balance, with positive energy dissipation rate in accord with the Clausius-Duhem inequality. Notably, these properties are not imposed but follow directly from the constitutive law and evolution equation when multiplying the equation of motion by the velocity and integrating by parts. In addition to elastic constants, the model requires at most three key material parameters: the strain at the onset of nonlinearity, the ultimate tensile strength, and the fracture toughness. The approach simplifies parameter identification while ensuring representation of material behavior. The approach seamlessly handles fracture evolution across loading regimes, from quasi-static to dynamic, accommodating both fast crack propagation and quasi-brittle failure under monotonic and cyclic loading. Numerical simulations show quantitative and qualitative agreement with experiments, including three-point bending tests on concrete. The model successfully captures the cyclic load-deflection response of crack mouth opening displacement, the structural size-effect related to ultimate load and specimen size, fracture originating from corner singularities in L- shaped domains, and bifurcating fast cracks.