| Autor: |
Osofsky MS; Naval Research Laboratory, Washington, DC, USA., Hernández SC; Naval Research Laboratory, Washington, DC, USA., Nath A; George Mason University, Fairfax, VA, USA., Wheeler VD; Naval Research Laboratory, Washington, DC, USA., Walton SG; Naval Research Laboratory, Washington, DC, USA., Krowne CM; Naval Research Laboratory, Washington, DC, USA., Gaskill DK; Naval Research Laboratory, Washington, DC, USA. |
| Abstrakt: |
Reports of metallic behavior in two-dimensional (2D) systems such as high mobility metal-oxide field effect transistors, insulating oxide interfaces, graphene, and MoS2 have challenged the well-known prediction of Abrahams, et al. that all 2D systems must be insulating. The existence of a metallic state for such a wide range of 2D systems thus reveals a wide gap in our understanding of 2D transport that has become more important as research in 2D systems expands. A key to understanding the 2D metallic state is the metal-insulator transition (MIT). In this report, we explore the nature of a disorder induced MIT in functionalized graphene, a model 2D system. Magneto-transport measurements show that weak-localization overwhelmingly drives the transition, in contradiction to theoretical assumptions that enhanced electron-electron interactions dominate. These results provide the first detailed picture of the nature of the transition from the metallic to insulating states of a 2D system. |
