Add to ORKGIn this contribution we describe a methodology for the study of softening brittle materials at different scales of observation. The goal is to account for a higher resolution at those areas that undergo the non-linear processes. We apply the FETI (Finite Element Tearing and Interconnecting) technique to glue different domain resolutions during the non-linear analysis. The present framework is suitable for multiscale problems in which the scale separation principle does not hold and, consequently, the use of classical homogenization techniques is no longer possible.Postprint (published version
In this study a FETI: Finite Element Tearing and Interconnecting [1] technique is adopted and exploi...
In this study a FETI: Finite Element Tearing and Interconnecting [1] technique is adopted and exploi...
In this study a FETI: Finite Element Tearing and Interconnecting [1] technique is adopted and exploi...
In this contribution we describe a methodology for the study of softening brittle materials at diffe...
In this contribution we describe a methodology for the study of softening brittle materials at diffe...
In this contribution we present a domain decomposition framework for the multiscale analysis of soft...
We focus on the analysis of fracture in quasi-brittle materials by exploiting the potential of domai...
In this contribution we present a multiscale framework for the analysis of brittle materials based o...
In this contribution we describe a methodology for the multiscale analysis of heterogeneous quasi-br...
In this contribution we present a multiscale framework for the analysis of brittle materials based o...
In this contribution we present a multiscale framework for the analysis of brittle materials based o...
In this contribution we present a multiscale framework for the analysis of brittle materials based o...
In this contribution we present a multiscale framework for the analysis of brittle materials based o...
Computational material design is progressively gaining momentum in the engineering world. Recent bre...
Computational material design is progressively gaining momentum in the engineering world. Recent bre...
In this study a FETI: Finite Element Tearing and Interconnecting [1] technique is adopted and exploi...
In this study a FETI: Finite Element Tearing and Interconnecting [1] technique is adopted and exploi...
In this study a FETI: Finite Element Tearing and Interconnecting [1] technique is adopted and exploi...
In this contribution we describe a methodology for the study of softening brittle materials at diffe...
In this contribution we describe a methodology for the study of softening brittle materials at diffe...
In this contribution we present a domain decomposition framework for the multiscale analysis of soft...
We focus on the analysis of fracture in quasi-brittle materials by exploiting the potential of domai...
In this contribution we present a multiscale framework for the analysis of brittle materials based o...
In this contribution we describe a methodology for the multiscale analysis of heterogeneous quasi-br...
In this contribution we present a multiscale framework for the analysis of brittle materials based o...
In this contribution we present a multiscale framework for the analysis of brittle materials based o...
In this contribution we present a multiscale framework for the analysis of brittle materials based o...
In this contribution we present a multiscale framework for the analysis of brittle materials based o...
Computational material design is progressively gaining momentum in the engineering world. Recent bre...
Computational material design is progressively gaining momentum in the engineering world. Recent bre...
In this study a FETI: Finite Element Tearing and Interconnecting [1] technique is adopted and exploi...
In this study a FETI: Finite Element Tearing and Interconnecting [1] technique is adopted and exploi...
In this study a FETI: Finite Element Tearing and Interconnecting [1] technique is adopted and exploi...