Study of failure mechanism in the modern IGBT with a highly doped N-buffer layer

Author

Chunlin Zhu ; Deviny, Ian ; Liu, Gary ; Dai, Andy

Author_Institution

Power Semicond. R&D Centre, Dynex Semicond. Ltd., Lincoln, UK

fYear

2014

Firstpage

1834

Lastpage

1839

Abstract

Modern IGBT structure with a highly doped buffer layer showed a MOSFET-like behavior at low collector-emitter voltage when the gate was fully turned-on. This significantly increased the conduction loss and resulted in scrap chips. Its failure mechanism has been systematically studied in this paper to reveal the underlying device physics inside the IGBT microstructure using energy-band theory, numerical simulation and equivalent circuit methods. It is reported that both tunneling current and low injection efficiency of highly doped p-emitter/n-buffer junction are root causes, and the latter deactivates the bipolar function, so that the device is dominated by MOSFET action only under low collector-emitter voltage condition. The paper will be concluded by presenting excellent measured performances of IGBTs using optimized p-emitter/n-buffer junction.

Keywords

failure analysis; insulated gate bipolar transistors; semiconductor device reliability; semiconductor doping; tunnelling; conduction loss; failure mechanism; highly doped N-buffer layer; low collector-emitter voltage; low injection efficiency; modern IGBT; scrap chips; tunneling current; Buffer layers; Charge carrier processes; Doping; Failure analysis; Insulated gate bipolar transistors; Integrated circuits; Junctions; IGBT; failure mechanism; injection efficiency; p-emitter/n-buffer junction; tunneling current;

fLanguage

English

Publisher

ieee

Conference_Titel

Industrial Electronics Society, IECON 2014 - 40th Annual Conference of the IEEE

Type

conf

DOI

10.1109/IECON.2014.7048751

Filename

7048751