Title :
Investigation of the Epitaxial Graphene/p-SiC Heterojunction
Author :
Anderson, T.J. ; Hobart, Karl D. ; Nyakiti, L.O. ; Wheeler, V.D. ; Myers-Ward, R.L. ; Caldwell, J.D. ; Bezares, F.J. ; Jernigan, G.G. ; Tadjer, M.J. ; Imhoff, E.A. ; Koehler, A.D. ; Gaskill, D.K. ; Eddy, C.R., Jr. ; Kub, F.J.
Author_Institution :
U.S. Naval Res. Lab., Washington, DC, USA
Abstract :
There has been significant research in the study of in-plane charge-carrier transport in graphene in order to understand and exploit its unique electrical properties; however, the vertical graphene-semiconductor system also presents opportunities for unique devices. In this letter, we investigate the epitaxial graphene/p-type 4H-SiC system to better understand this vertical heterojunction. The I-V behavior does not demonstrate thermionic emission properties that are indicative of a Schottky barrier but rather demonstrates characteristics of a semiconductor heterojunction. This is confirmed by the fitting of the temperature-dependent I-V curves to classical heterojunction equations and the observation of band-edge electroluminescence in SiC.
Keywords :
Schottky barriers; electroluminescence; graphene; semiconductor heterojunctions; silicon compounds; thermionic emission; I-V behavior; Schottky barrier; SiC; band-edge electroluminescence; epitaxial graphene-p-SiC heterojunction; graphene-semiconductor system; in-plane charge-carrier transport; thermionic emission properties; unique electrical properties; Epitaxial growth; Graphene; Heterojunctions; Silicon carbide; Thermionic emission; Graphene; heterojunction; semiconductor (SiC);
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2012.2211562
