Long-term prediction test procedure for most ICs, based on linear response theory
Abstract
Experimentally, thermal annealing is known to be a factor which enables a number of different integrated circuits (IC's) to recover their operating characteristics after suffering radiation damage in the space radiation environment; thus, decreasing and limiting long term cumulative total-dose effects. This annealing is also known to be accelerated at elevated temperatures both during and after irradiation. Linear response theory (LRT) was applied, and a linear response function (LRF) to predict the radiation/annealing response of sensitive parameters of IC's for long term (several months or years) exposure to the space radiation environment were constructed. Compressing the annealing process from several years in orbit to just a few hours or days in the laboratory is achieved by subjecting the IC to elevated temperatures or by increasing the typical spaceflight dose rate by several orders of magnitude for simultaneous radiation/annealing only. The accomplishments are as follows: (1) the test procedure to make predictions of the radiation response was developed; (2) the calculation of the shift in the threshold potential due to the charge distribution in the oxide was written; (3) electron tunneling processes from the bulk Si to the oxide region in an MOS IC were estimated; (4) in order to connect the experimental annealing data to the theoretical model, constants of the model of the basic annealing process were established; (5) experimental data obtained at elevated temperatures were analyzed; (6) time compression and reliability of predictions for the long term region were shown; (7) a method to compress test time and to make predictions of response for the nonlinear region was proposed; and (8) nonlinearity of the LRF with respect to log(t) was calculated theoretically from a model.
- Publication:
-
Final Report Catholic Univ. of America
- Pub Date:
- April 1991
- Bibcode:
- 1991cua..rept.....L
- Keywords:
-
- Accelerated Life Tests;
- Annealing;
- Dynamic Response;
- Integrated Circuits;
- Linear Systems;
- Prediction Analysis Techniques;
- Radiation Damage;
- Space Environment Simulation;
- Electron Tunneling;
- High Temperature;
- Irradiation;
- Mathematical Models;
- Metal Oxide Semiconductors;
- Temperature Effects;
- Electronics and Electrical Engineering