Mechanical behavior of ultralight nickel metamaterial

The mechanical response of ultralight kagome structures consisting of hollow nickel (Ni) nanotubes and solid Ni nanorods to compression is studied using molecular dynamics simulations. In both kagome architectures, 1 6 [ 112 ] Shockley partial dislocations and twin formation are observed under compression. The structure made from solid nanorods shows deformation near both the nodes and beams of the kagome lattice. The hollow kagome architecture has a higher yield point than the solid kagome structure. The deformation in the hollow nanotube structure is mostly localized in the nodal region for strains less than 11%. At higher strains, the deformation sets in all the struts and nodes of the hollow kagome lattice. Owing to this two-stage deformation mechanism, the hollow Ni nanotube kagome structure shows less bending and greater toughness than the solid Ni nanorod kagome architecture.

Automated summary

The mechanical response to compression of ultralight kagome structures consisting of hollow nickel nanotubes and solid nickel nanorods was studied. Partial dislocations and twin formation were observed in both kagome architectures. The hollow kagome structure had a higher yield point than the solid kagome structure, with deformation mainly localized in the nodal region for strains less than 11%.