Abstract

The electronic band-gap properties of high-density, highly tetrahedrally bonded, hydrogenated amorphous carbon are related to the size and overlap distribution of small \ensuremath{\pi}-bonded clusters embedded within a strained rigid ${\mathit{sp}}^{3}$ matrix of atomic-scale models generated by semiempirical density-functional molecular dynamics. Compared to the hydrogen-free analogues of similar density and chemical composition, the residual strain in the network is reduced. As a consequence the overlap of p orbitals between undercoordinated sites is enforced in favor of forming strong \ensuremath{\pi} bonds, which is consistent with a further band-gap opening relative to the hydrogen-free structures.