We use ab initio density-functional calculations to determine the interaction of a graphene monolayer with the Si(111) surface. We find that graphene forms strong bonds to the bare substrate and accommodates the 12% lattice mismatch by forming a wavy structure consisting of free-standing conductive ridges that are connected by ribbon-shaped regions of graphene, which bond covalently to the substrate. We perform quantum transport calculations for different geometries to study changes in the transport properties of graphene introduced by the wavy structure and bonding to the Si substrate. Our results suggest that wavy graphene combines high mobility along the ridges with efficient carrier injection into Si in the contact regions. © 2013 American Physical Society
Tayran, C., Zhu, Z., Baldoni, M., Selli, D., Seifert, G., Tománek, D. (2013). Optimizing electronic structure and quantum transport at the graphene-Si(111) Interface: An ab initio density-functional study. PHYSICAL REVIEW LETTERS, 110(17) [10.1103/PhysRevLett.110.176805].
Optimizing electronic structure and quantum transport at the graphene-Si(111) Interface: An ab initio density-functional study
SELLI, DANIELE;
2013
Abstract
We use ab initio density-functional calculations to determine the interaction of a graphene monolayer with the Si(111) surface. We find that graphene forms strong bonds to the bare substrate and accommodates the 12% lattice mismatch by forming a wavy structure consisting of free-standing conductive ridges that are connected by ribbon-shaped regions of graphene, which bond covalently to the substrate. We perform quantum transport calculations for different geometries to study changes in the transport properties of graphene introduced by the wavy structure and bonding to the Si substrate. Our results suggest that wavy graphene combines high mobility along the ridges with efficient carrier injection into Si in the contact regions. © 2013 American Physical Society
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