Title :
A Scalable Electrothermal Model for Transient Self-Heating Effects in Trench-Isolated SiGe HBTs
Author :
Sahoo, Amit Kumar ; Frégonèse, Sébastien ; Weis, M. ; Malbert, Nathalie ; Zimmer, Thomas
Author_Institution :
IMS Lab., Univ. Bordeaux 1, Talence, France
Abstract :
This paper demonstrates a scalable electrothermal model for transient self-heating effects in trench-isolated SiGe heterojunction bipolar transistors (HBTs). The scalability of the thermal model has been investigated by considering pyramidal heat diffusion approximation between the heat source and the thermal ground. Three-dimensional thermal TCAD simulations have been carried out to obtain transient variations of the junction temperature and to extract the thermal impedance in the frequency domain. A recursive thermal network with scalable model parameters has been developed and added at the temperature node of the HBT compact model HiCuM. This network has been verified through numerical simulations and by low-frequency s-parameter measurements and found to be in excellent agreement for various device geometries.
Keywords :
Ge-Si alloys; S-parameters; frequency-domain analysis; heterojunction bipolar transistors; numerical analysis; semiconductor device measurement; semiconductor device models; semiconductor materials; thermal analysis; HiCuM HBT compact model; SiGe; frequency domain; heat source; heterojunction bipolar transistors; junction temperature; low-frequency S-parameter measurements; numerical simulations; pyramidal heat diffusion approximation; recursive thermal network; scalable electrothermal model; scalable model parameters; thermal ground; thermal impedance extraction; three-dimensional thermal TCAD simulations; transient self-heating effects; trench-isolated HBT; Approximation methods; Geometry; Heating; Numerical models; Temperature measurement; Transient analysis; Transistors; Bipolar transistors; electrothermal effects; numerical simulation; semiconductor device modeling; thermal impedance measurements; thermal resistance;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2012.2209651
