Title :
Temperature effect on ultra thin SiO2 time-dependent-dielectric-breakdown
Author_Institution :
Electr. & Comput. Eng., Rutgers Univ., Piscataway, NJ, USA
Abstract :
The unusually high temperature-acceleration factor and the non-Arrhenius behavior of ultra thin oxide can be explained by kinetic analysis using the physics-based kinetic model of oxide defect generation during electrical stress. The semi-quantitative treatment using known experimental value range is in good agreement with the reported data in the literature, lending strong support for the kinetic model. The estimated activation energy difference between thick and thin oxide relies on the fact that for thick oxide the hole current to electron current ratio is approximately constant. The resulting agreement with reported data lend support to the anode-hole-injection model (under high-field stress) unless the hydrogen release per injected electron happens to be of a similar order of magnitude.
Keywords :
MIS structures; dielectric thin films; electric breakdown; kinetic theory; silicon compounds; MOS structure; Si-SiO2; activation energy difference; anode-hole-injection model; electrical stress; high-field stress; hole current to electron current ratio; hydrogen release; kinetic analysis; nonArrhenius behavior; oxide defect generation; physics-based kinetic model; semiquantitative treatment; temperature effect; temperature-acceleration factor; time-dependent-dielectric-breakdown; ultra thin SiO2; ultra thin oxide; Charge carrier processes; Current density; Electric breakdown; Electrons; Equations; Kinetic theory; Stress; Temperature; Tunneling; Voltage;
Conference_Titel :
Plasma- and Process-Induced Damage, 2003 8th International Symposium
Print_ISBN :
0-7803-7747-8
DOI :
10.1109/PPID.2003.1200941
