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This book offers a collection of six papers addressing problems associated with the computational modeling of multi-field problems. Some of the proposed contributions present novel computational techniques, while other topics focus on applying state-of-the-art techniques in order to solve coupled problems in various areas including the prediction of material failure during the lithiation process, which is of major importance in batteries; efficient models for flexoelectricity, which require higher-order continuity; the prediction of composite pipes under thermomechanical conditions; material failure in rock; and computational materials design. The latter exploits nano-scale modeling in order to predict various material properties for two-dimensional materials with applications in, for example, semiconductors. In summary, this book provides a good overview of the computational modeling of different multi-field problems.
temperature variation --- h-BN and Graphene sheets --- molecular dynamics simulation --- thermal conductance --- mechanical --- patch repair --- first-principles --- finite element method --- Von Mises stress --- composite --- thermal --- electrofusion socket joints --- two-dimensional semiconductor --- buried gas distribution pipes --- level set technique --- lithium-ion battery --- phase field approach to fracture --- meshless method --- rock mechanics --- fracture of geo-materials --- flexoelectricity --- pressure gradient effect --- medium density polyethylene (MDPE) --- high density polyethylene (HDPE) --- size effect --- fracture analysis --- interface modeling --- cohesive zone model --- thermal conductivity --- peridynamics
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