Moving current filaments in integrated DMOS transistors under short-duration current stress

Author

Denison, Marie ; Blaho, Matej ; Rodin, Pavel ; Dubec, Viktor ; Pogany, Dionyz ; Silber, Dieter ; Gornik, Erich ; Stecher, Matthias

Author_Institution

Infineon Technol. AG, Munich, Germany

Volume

51

Issue

8

fYear

2004

Firstpage

1331

Lastpage

1339

Abstract

Integrated vertical DMOS transistors of a 90-V smart power technology are studied under short-duration current pulses. Movement of current filaments and multiple hot spots observed by transient interferometric mapping under nondestructive snap-back conditions are reported. Device simulations show that the base push-out region associated with the filament can move from cell to cell along the drain buried layer due to the decrease of the avalanche generation rates by increasing temperature. The influence of the termination layout of the source field on the hot-spot dynamics is studied. Conditions for filament motion are discussed. The described mechanisms help homogenizing the time averaged current-density distribution and enhance the device robustness against electrostatic discharges.

Keywords

MOS integrated circuits; circuit simulation; current density; current distribution; electrostatic discharge; photothermal effects; 90 V; avalanche generation rates; base push-out region; current filaments; device robustness; drain buried layer; electrostatic discharges; electrothermal effects; electrothermal simulations; hot-spot dynamics; integrated DMOS transistors; multiple hot spots; nondestructive snap-back conditions; photothermal effects; power semiconductor devices; short-duration current pulse; short-duration current stress; smart power technology; source field termination layout; time averaged current-density distribution; transient interferometric mapping; vertical DMOS transistors; Analytical models; Electrostatic discharge; Electrothermal effects; Photothermal effects; Protection; Robustness; Solid state circuits; Stress; Temperature; Vehicle dynamics; BCD; DMOS; ESDs; current filaments; electrostatic discharges; electrothermal effects; electrothermal simulations; photothermal effects; power semiconductor devices; smart power;

fLanguage

English

Journal_Title

Electron Devices, IEEE Transactions on

Publisher

ieee

ISSN

0018-9383

Type

jour

DOI

10.1109/TED.2004.832097

Filename

1317157