Publication Date:
2011
abstract:
Defects in cubic silicon carbide (3C-SiC) epilayers, that were grown using different techniques and on different substrates, were studied in terms of electrical activity and device limiting implications. An electrical characterization by conductive atomic force microscopy (C-AFM) showed that stacking faults (SFs) are normally the predominant type of defects that are electrically active at the semiconductor surface and, therefore, the most important defects that can affect the contact properties on these epilayers. It is also shown that an ultraviolet (UV) irradiation process can be used to suppress detrimental leakage currents passing through SFs that are carbon terminated at the semiconductor surface. Indeed, current-voltage characterization of Au/3C-SiC diodes showed a subsequent improvement of the Schottky behavior. (c) (2011) Trans Tech Publications.
Iris type:
01.01 Articolo in rivista
Keywords:
3C-SiC; Conductive AFM; Conductive atomic force microscopy; Contact properties; Cubic silicon carbide (3C-SiC); Current-voltage characterization; Different substrates; Electrical activities; Electrical characterization; Schottky behaviors; Schottky contacts; Semi-conductor surfaces; SiC diodes; Structural defect; Ultraviolet irradiations; Atomic force microscopy; Electric properties; Epilayers; Epitaxial growth; Leakage currents; Passivation; Silicon carbide; Stacking faults; Surface defects; Semiconducting silicon compounds
List of contributors:
Eriksson, GUSTAV JENS PETER; Weng, MING HUNG; Raineri, Vito; Roccaforte, Fabrizio; Giannazzo, Filippo
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