Add to ORKGThe microstructural basis of the characteristic nonlinear mechanics of biopolymernetworks remains unclear. We present a 3D network model of realistic, cross-linked semiflexible fibers to study strain-stiffening and the effect of fiber volume-occupancy. We identify two structural parameters, namely, network connectivity and fiber entanglements, that fully govern the nonlinear response from small to large strains. The results also reveal distinct deformation mechanisms at different length scales and, in particular, the contributions of heterogeneity at short length scales
Random networks of semiflexible filaments are common support structures in biology. Familiar example...
Cross-linked polymer networks are stress supporting structures that represent an important class of ...
Biological and polymeric networks show highly nonlinear stress-strain behavior manifested in materia...
The microstructural basis of the characteristic nonlinear mechanics of biopolymernetworks remains un...
The microstructural basis of the characteristic nonlinear mechanics of biopolymernetworks remains un...
The microstructural basis of the characteristic nonlinear mechanics of biopolymernetworks remains un...
The microstructural basis of the characteristic nonlinear mechanics of biopolymernetworks remains un...
The microstructural basis of the characteristic nonlinear mechanics of biopolymernetworks remains un...
International audienceCross-linked semiflexible polymer networks are omnipresent in living cells. Ty...
International audienceCross-linked semiflexible polymer networks are omnipresent in living cells. Ty...
Biopolymer networks, such as those constituting the cytoskeleton of a cell or biological tissue, exh...
Many biological systems involve intricate, hierarchical networks formed from cross-linked filaments,...
In a recent publication, we studied the mechanical stiffening behavior in two-dimensional (2D) cross...
In a recent publication, we studied the mechanical stiffening behavior in two-dimensional (2D) cross...
In a recent publication, we studied the mechanical stiffening behavior in two-dimensional (2D) cross...
Random networks of semiflexible filaments are common support structures in biology. Familiar example...
Cross-linked polymer networks are stress supporting structures that represent an important class of ...
Biological and polymeric networks show highly nonlinear stress-strain behavior manifested in materia...
The microstructural basis of the characteristic nonlinear mechanics of biopolymernetworks remains un...
The microstructural basis of the characteristic nonlinear mechanics of biopolymernetworks remains un...
The microstructural basis of the characteristic nonlinear mechanics of biopolymernetworks remains un...
The microstructural basis of the characteristic nonlinear mechanics of biopolymernetworks remains un...
The microstructural basis of the characteristic nonlinear mechanics of biopolymernetworks remains un...
International audienceCross-linked semiflexible polymer networks are omnipresent in living cells. Ty...
International audienceCross-linked semiflexible polymer networks are omnipresent in living cells. Ty...
Biopolymer networks, such as those constituting the cytoskeleton of a cell or biological tissue, exh...
Many biological systems involve intricate, hierarchical networks formed from cross-linked filaments,...
In a recent publication, we studied the mechanical stiffening behavior in two-dimensional (2D) cross...
In a recent publication, we studied the mechanical stiffening behavior in two-dimensional (2D) cross...
In a recent publication, we studied the mechanical stiffening behavior in two-dimensional (2D) cross...
Random networks of semiflexible filaments are common support structures in biology. Familiar example...
Cross-linked polymer networks are stress supporting structures that represent an important class of ...
Biological and polymeric networks show highly nonlinear stress-strain behavior manifested in materia...