Identifying failure mechanisms in LDMOS transistors by analytical stability analysis

Alessandro  Ferrara; Peter Steeneken; Boni K. Boksteen; Anco Heringa; AJ Scholten; Jurriaan Schmitz; Raymond J.E. Hueting

doi:10.1109/ESSDERC.2014.6948825

Identifying failure mechanisms in LDMOS transistors by analytical stability analysis

Alessandro Ferrara, Peter Steeneken, Boni K. Boksteen, Anco Heringa, AJ Scholten, Jurriaan Schmitz, Raymond J.E. Hueting

QN/Steeneken Lab

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

2 Citations (Scopus)

Abstract

In this work, analytical stability equations are derived and combined with a physics-based model of an LDMOS transistor in order to identify the primary cause of failure in different operating and bias conditions. It is found that there is a gradual boundary between an electrical failure region at high drain voltage and a thermal failure region at high junction temperature. The theoretical results are mapped onto a 3D space comprising gate-width normalized drain current, drain voltage and junction temperature, allowing an immediate visualization of the different failure mechanisms. The validity of the proposed analysis is supported by measurements of the safe operating limits of silicon-on-insulator (SOI) LDMOS transistors.

Original language	English
Title of host publication	Proceedings of the 44th European Solid‐State Device Research Conference (ESSDERC 2014)
Place of Publication	Piscataway
Publisher	IEEE
Pages	321-324
DOIs	https://doi.org/10.1109/ESSDERC.2014.6948825
Publication status	Published - 2014
Event	ESSDERC 2014, Venice, Italy - Piscataway, NJ, USA Duration: 22 Sept 2014 → 26 Sept 2014

Conference

Conference	ESSDERC 2014, Venice, Italy
Period	22/09/14 → 26/09/14

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10.1109/ESSDERC.2014.6948825

Cite this

@inproceedings{daba41cdfa7d4da88485b9406c16f9b8,

title = "Identifying failure mechanisms in LDMOS transistors by analytical stability analysis",

abstract = "In this work, analytical stability equations are derived and combined with a physics-based model of an LDMOS transistor in order to identify the primary cause of failure in different operating and bias conditions. It is found that there is a gradual boundary between an electrical failure region at high drain voltage and a thermal failure region at high junction temperature. The theoretical results are mapped onto a 3D space comprising gate-width normalized drain current, drain voltage and junction temperature, allowing an immediate visualization of the different failure mechanisms. The validity of the proposed analysis is supported by measurements of the safe operating limits of silicon-on-insulator (SOI) LDMOS transistors.",

author = "Alessandro Ferrara and Peter Steeneken and Boksteen, {Boni K.} and Anco Heringa and AJ Scholten and Jurriaan Schmitz and Hueting, {Raymond J.E.}",

year = "2014",

doi = "10.1109/ESSDERC.2014.6948825",

language = "English",

pages = "321--324",

booktitle = "Proceedings of the 44th European Solid‐State Device Research Conference (ESSDERC 2014)",

publisher = "IEEE",

address = "United States",

note = "ESSDERC 2014, Venice, Italy ; Conference date: 22-09-2014 Through 26-09-2014",

}

Ferrara, A, Steeneken, P, Boksteen, BK, Heringa, A, Scholten, AJ, Schmitz, J & Hueting, RJE 2014, Identifying failure mechanisms in LDMOS transistors by analytical stability analysis. in Proceedings of the 44th European Solid‐State Device Research Conference (ESSDERC 2014). IEEE, Piscataway, pp. 321-324, ESSDERC 2014, Venice, Italy, 22/09/14. https://doi.org/10.1109/ESSDERC.2014.6948825

Identifying failure mechanisms in LDMOS transistors by analytical stability analysis. / Ferrara, Alessandro ; Steeneken, Peter; Boksteen, Boni K. et al.
Proceedings of the 44th European Solid‐State Device Research Conference (ESSDERC 2014). Piscataway: IEEE, 2014. p. 321-324.

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

TY - GEN

T1 - Identifying failure mechanisms in LDMOS transistors by analytical stability analysis

AU - Ferrara, Alessandro

AU - Steeneken, Peter

AU - Boksteen, Boni K.

AU - Heringa, Anco

AU - Scholten, AJ

AU - Schmitz, Jurriaan

AU - Hueting, Raymond J.E.

PY - 2014

Y1 - 2014

N2 - In this work, analytical stability equations are derived and combined with a physics-based model of an LDMOS transistor in order to identify the primary cause of failure in different operating and bias conditions. It is found that there is a gradual boundary between an electrical failure region at high drain voltage and a thermal failure region at high junction temperature. The theoretical results are mapped onto a 3D space comprising gate-width normalized drain current, drain voltage and junction temperature, allowing an immediate visualization of the different failure mechanisms. The validity of the proposed analysis is supported by measurements of the safe operating limits of silicon-on-insulator (SOI) LDMOS transistors.

AB - In this work, analytical stability equations are derived and combined with a physics-based model of an LDMOS transistor in order to identify the primary cause of failure in different operating and bias conditions. It is found that there is a gradual boundary between an electrical failure region at high drain voltage and a thermal failure region at high junction temperature. The theoretical results are mapped onto a 3D space comprising gate-width normalized drain current, drain voltage and junction temperature, allowing an immediate visualization of the different failure mechanisms. The validity of the proposed analysis is supported by measurements of the safe operating limits of silicon-on-insulator (SOI) LDMOS transistors.

U2 - 10.1109/ESSDERC.2014.6948825

DO - 10.1109/ESSDERC.2014.6948825

M3 - Conference contribution

SP - 321

EP - 324

BT - Proceedings of the 44th European Solid‐State Device Research Conference (ESSDERC 2014)

PB - IEEE

CY - Piscataway

T2 - ESSDERC 2014, Venice, Italy

Y2 - 22 September 2014 through 26 September 2014

ER -

Identifying failure mechanisms in LDMOS transistors by analytical stability analysis

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