Title :
An electrothermal model of memory switching in vertical polycrystalline silicon structures
Author :
Malhotra, Vinod ; Mahan, John E. ; Ellsworth, Daniel L.
Author_Institution :
Dept. of Electr. Eng., Colorado State Univ., Fort Collins, CO, USA
fDate :
9/1/1988 12:00:00 AM
Abstract :
The theoretical preswitching temperature, resistivity, and current-density distributions within the thin-film device were obtained from the solution of the transient two-dimensional heat equation. The results of the computer simulation, obtained for the case where conductivity is dependent on both temperature and electric field, show that current crowding occurs at the center of the device and that thermal runaway develops in a few tens of nanoseconds for voltages above a critical value. A simulated conductive irregularity forces the filament to nucleate away from the center and closer to or at the inhomogeneity. The excellent agreement between the experimental data and the simulation lends support to the idea that the fundamental switching mechanism is thermal in nature
Keywords :
elemental semiconductors; semiconductor device models; semiconductor storage; silicon; switching; computer simulation; conductivity; current crowding; current-density distributions; electric field; electrothermal model; memory switching; polycrystalline Si structures; preswitching temperature; resistivity; semiconductor device; simulated conductive irregularity; thermal runaway; thin-film device; transient two-dimensional heat equation; Computer simulation; Electrothermal effects; Equations; Nanoscale devices; Proximity effect; Temperature dependence; Temperature distribution; Thermal conductivity; Thin film devices; Voltage;
Journal_Title :
Electron Devices, IEEE Transactions on
