Title :
Investigation of SILC via Energy Resolved spin dependent tunneling spectroscopy
Author :
Ryan, J.T. ; Lenahan, P.M. ; Krishnan, A.T. ; Krishnan, S.
Author_Institution :
Pennsylvania State Univ., University Park, PA, USA
Abstract :
We demonstrate voltage controlled spin dependent tunneling in 1.2 nm effective oxide thickness silicon oxynitride films. Our observations introduce a simple method to link point defect structure and energy levels in a very direct way in materials of great technological importance. We obtain defect energy level resolution by exploiting the enormous difference between the capacitance of the very thin dielectric and the capacitance of the depletion layer of moderately doped silicon. The simplicity of the technique and the robust character of the response make it, at least potentially, of widespread utility in the understanding of defects important in solid state electronics. Since the specific defect observed is generated by high electric field stressing, an important device instability in present day integrated circuitry, the observations are of considerable importance for present day technology.
Keywords :
elemental semiconductors; leakage currents; point defects; semiconductor device reliability; semiconductor-insulator-semiconductor devices; silicon; silicon compounds; stress effects; tunnelling spectroscopy; SILC; Si-SiOxNy; defect energy level resolution; electric field stressing; energy resolved spin dependent tunneling spectroscopy; oxide thickness; point defect structure; silicon oxynitride films; size 1.2 nm; solid state electronics; stress induced leakage currents; Capacitance; Dielectric materials; Energy resolution; Energy states; Semiconductor films; Silicon; Spectroscopy; Thickness control; Tunneling; Voltage control;
Conference_Titel :
Integrated Reliability Workshop Final Report, 2009. IRW '09. IEEE International
Conference_Location :
S. Lake Tahoe, CA
Print_ISBN :
978-1-4244-3921-8
Electronic_ISBN :
1930-8841
DOI :
10.1109/IRWS.2009.5383043
