Title :
Simulations of electric field domain suppression in a superlattice oscillator device using a distributed circuit model
Author :
Daniel, Erik S. ; Gilbert, Barry K. ; Scott, Jeffrey S. ; Allen, S. James
Author_Institution :
Special Purpose Processor Dev. Group, Mayo Found., Rochester, MN, USA
Abstract :
We present a method for simulating static domain formation in distributed negative differential resistance devices using a distributed circuit array model coupled with quantum transport simulations. This simulation method is applied to the case of a superlattice Bloch oscillator to ascertain the efficacy of electric field domain wall suppression by micro shunt side walls. Two independent simulation mechanisms using the same basic distributed circuit model are employed to separate simulation artifacts from true physical trends. Simulations are presented, suggesting that the presence of the micro shunt can suppress domain formation above a critical device bias voltage. The simulated dependence of this critical voltage on macroscopic device parameters is presented.
Keywords :
SPICE; electric domain walls; negative resistance devices; semiconductor device models; semiconductor superlattices; submillimetre wave oscillators; HSPICE; critical device bias voltage; distributed circuit model; distributed negative differential resistance devices; domain wall suppression; electric field domain suppression; macroscopic device parameters; micro shunt side walls; multiquantum well superlattice; quantum transport simulations; simulation method; solid-state terahertz oscillator; static domain formation; superlattice Bloch oscillator; superlattice oscillator device; vertical voltage difference; Anisotropic magnetoresistance; Chemical technology; Circuit simulation; Electromagnetic spectrum; Oscillators; Physics; Semiconductor materials; Solid state circuits; Submillimeter wave technology; Superlattices;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2003.819255
