Title :
Computer analysis of the negative differential resistance switching phenomenon of double-injection devices
Author_Institution :
Dept. of Electr. Eng., Texas Univ., Arlington, TX, USA
fDate :
9/1/1989 12:00:00 AM
Abstract :
By directly solving the semiconductor differential equations for the double-injection (DI) devices involving two interacting deep levels, the authors studied the negative differential resistance switching characteristic and its relationship with the device dimension, doping level, and dependence on the deep impurity profile. Computer simulation showed that although one can increase the threshold voltage by increasing the device length, the excessive holding voltage that would follow would put this device in a very limited application such as pulse power source. The excessive leakage current in the low conductance state also jeopardizes the attempt to use the device for any practical purpose. Unless there are new materials and deep impurities found that have a large differential hole and electron capture cross sections and a reasonable energy bandgap for low intrinsic carrier concentration, no significant improvement in the fate of DI devices is expected in the near future
Keywords :
computer aided analysis; deep levels; doping profiles; electronic engineering computing; impurity distribution; leakage currents; negative resistance effects; semiconductor device models; semiconductor switches; switching; computer analysis; deep impurity profile; device dimension; doping level; double-injection devices; holding voltage; leakage current; low conductance state; negative differential resistance switching; semiconductor; semiconductor differential equations; threshold voltage; two interacting deep levels; Application software; Computer simulation; Conducting materials; Differential equations; Doping profiles; Leakage current; Radioactive decay; Semiconductor device doping; Semiconductor impurities; Threshold voltage;
Journal_Title :
Electron Devices, IEEE Transactions on
