Title :
Investigation of Junction Thermal Characteristics of Light-Emitting Transistors
Author :
Hao-Hsiang Yang ; Hsiao-Lun Wang ; Chao-Hsin Wu
Author_Institution :
Nat. Taiwan Univ., Taipei, Taiwan
Abstract :
Self-heating effect is the main contribution to the junction temperature in bipolar junction transistors. In this paper, the dc temperature-variation measurement and extraction method, including thermal-electric feedback coefficient of an InGaP/GaAs light-emitting transistor (LET), are presented. The thermal-electric feedback coefficient of the LET is -2.07 mV/K at collector current of 2 mA and the thermal resistance is 993.3°C/W when the corresponding power dissipation is 44.19 mW. The thermal properties of the conventional heterojunciton bipolar transistor is also demonstrated and compared. The differences can be attributed to the quantum-well thermionic emission mechanisms and enhanced radiative recombination in the LET.
Keywords :
III-V semiconductors; gallium arsenide; heterojunction bipolar transistors; indium compounds; light emitting devices; quantum well devices; temperature measurement; thermal resistance; thermionic emission; DC temperature-variation extraction method; DC temperature-variation measurement; InGaP-GaAs; LET; current 2 mA; enhanced radiative recombination; heterojunciton bipolar transistor; junction temperature; junction thermal characteristics; light-emitting transistor; power 44.19 mW; power dissipation; quantum-well thermionic emission mechanism; self-heating effect; thermal resistance; thermal-electric feedback coefficient; Heterojunction bipolar transistors; Integrated circuits; Junctions; Temperature measurement; Temperature sensors; Thermal resistance; Junction temperature; light-emitting transistors (LETs); thermal resistance; thermal-electric feedback coefficient; thermal-electric feedback coefficient.;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2015.2389523
