Add to ORKGWe report molecular dynamics simulations of shear in a biomimetic hydroxyapatite-collagen composite. Our model exhibits elastic properties fully dominated by the inorganic component. However, beyond the elastic regime the biomolecules along with the hierarchical nature of the composite account for the formation of structure-inherent slip zones. These accommodate shear without compromising the overall structure and lead to the sliding of intrinsically defined rods at roughly constant restoring force. Upon releasing load, rod displacement is reversible and backcreep is observed as gradual ionic rearrangement in the slip zone, subjected to an activation barrier
Bone is a highly hierarchical complex structure that consists of organic and mineral components repr...
Many biological composite materials such as bone have demonstrated unique mechanical performance, i....
A fundamental study of the mechanics at the molecular scale and bridging it to the continuum level t...
We report molecular dynamics simulations of shear in a biomimetic hydroxyapatite-collagen composite....
We report molecular dynamics simulations of shear in a biomimetic hydroxyapatite-collagen composite....
<p>For clarity, only the calcium ions and the collagen molecules (green) are shown. Calcium ions are...
Bone, a hard biological material, possesses a combination of high stiffness and toughness, even thou...
Fracture mechanisms of an enamel-like hydroxyapatite-collagen composite model are elaborated by mean...
Bone is a hierarchical biological composite made of a mineral component (hydroxyapatite crystals) an...
Biological composite materials, such as bone, tooth and nacre, are comprised of a mixture of nano-si...
Bone at the nanoscale consists of type I collagen and hydroxyapatite (HAP). Type I collagen and HAP ...
In this work, a molecular dynamics simulation study of the collagen/apatite composite system is pres...
Hard biomaterials such as bone, dentin, and nacre show remarkable mechanical performance and serve a...
This thesis is a comprehensive study of deformation and failure mechanisms in bone at nano- and micr...
In many biological materials, the interfacial behaviour between constituents such as protein and min...
Bone is a highly hierarchical complex structure that consists of organic and mineral components repr...
Many biological composite materials such as bone have demonstrated unique mechanical performance, i....
A fundamental study of the mechanics at the molecular scale and bridging it to the continuum level t...
We report molecular dynamics simulations of shear in a biomimetic hydroxyapatite-collagen composite....
We report molecular dynamics simulations of shear in a biomimetic hydroxyapatite-collagen composite....
<p>For clarity, only the calcium ions and the collagen molecules (green) are shown. Calcium ions are...
Bone, a hard biological material, possesses a combination of high stiffness and toughness, even thou...
Fracture mechanisms of an enamel-like hydroxyapatite-collagen composite model are elaborated by mean...
Bone is a hierarchical biological composite made of a mineral component (hydroxyapatite crystals) an...
Biological composite materials, such as bone, tooth and nacre, are comprised of a mixture of nano-si...
Bone at the nanoscale consists of type I collagen and hydroxyapatite (HAP). Type I collagen and HAP ...
In this work, a molecular dynamics simulation study of the collagen/apatite composite system is pres...
Hard biomaterials such as bone, dentin, and nacre show remarkable mechanical performance and serve a...
This thesis is a comprehensive study of deformation and failure mechanisms in bone at nano- and micr...
In many biological materials, the interfacial behaviour between constituents such as protein and min...
Bone is a highly hierarchical complex structure that consists of organic and mineral components repr...
Many biological composite materials such as bone have demonstrated unique mechanical performance, i....
A fundamental study of the mechanics at the molecular scale and bridging it to the continuum level t...