Investigation of intrinsic dielectric breakdown mechanism in Cu/low-κ interconnect system

Nam Hwang; Tam Lyn Tan; Cheng Kuo Cheng; Anyan Du; Chee Lip Gan; Kin Leong Pey

doi:10.1109/LED.2006.871541

Investigation of intrinsic dielectric breakdown mechanism in Cu/low-κ interconnect system

Nam Hwang^*, Tam Lyn Tan, Cheng Kuo Cheng, Anyan Du, Chee Lip Gan, Kin Leong Pey

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

Abstract

Using a specifically designed test structure applying human body model electrostatic discharge (ESD) stress, the origin of dielectric breakdown in Cu/low-κ interconnect systems was found to be in interfacial delamination. The interfacial delamination between a SiC capping layer and a SiOC interdielectric layer is responsible for the increase of intermetal dielectric leakage current, causing high current Joule heating as well as catastrophic thermal breakdown. Also, the defect density increased as the delamination becomes wider while the number of ESD zaps increases.

Original language	English
Pages (from-to)	234-236
Number of pages	3
Journal	IEEE Electron Device Letters
Volume	27
Issue number	4
DOIs	https://doi.org/10.1109/LED.2006.871541
Publication status	Published - Apr 2006
Externally published	Yes

ASJC Scopus Subject Areas

Electronic, Optical and Magnetic Materials
Electrical and Electronic Engineering

Keywords

Delamination
Dielectric breakdown
Interconnect
Leakage current

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10.1109/LED.2006.871541

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abstract = "Using a specifically designed test structure applying human body model electrostatic discharge (ESD) stress, the origin of dielectric breakdown in Cu/low-κ interconnect systems was found to be in interfacial delamination. The interfacial delamination between a SiC capping layer and a SiOC interdielectric layer is responsible for the increase of intermetal dielectric leakage current, causing high current Joule heating as well as catastrophic thermal breakdown. Also, the defect density increased as the delamination becomes wider while the number of ESD zaps increases.",

keywords = "Delamination, Dielectric breakdown, Interconnect, Leakage current",

author = "Nam Hwang and Tan, {Tam Lyn} and Cheng, {Cheng Kuo} and Anyan Du and Gan, {Chee Lip} and Pey, {Kin Leong}",

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T1 - Investigation of intrinsic dielectric breakdown mechanism in Cu/low-κ interconnect system

AU - Hwang, Nam

AU - Tan, Tam Lyn

AU - Cheng, Cheng Kuo

AU - Du, Anyan

AU - Gan, Chee Lip

AU - Pey, Kin Leong

PY - 2006/4

Y1 - 2006/4

N2 - Using a specifically designed test structure applying human body model electrostatic discharge (ESD) stress, the origin of dielectric breakdown in Cu/low-κ interconnect systems was found to be in interfacial delamination. The interfacial delamination between a SiC capping layer and a SiOC interdielectric layer is responsible for the increase of intermetal dielectric leakage current, causing high current Joule heating as well as catastrophic thermal breakdown. Also, the defect density increased as the delamination becomes wider while the number of ESD zaps increases.

AB - Using a specifically designed test structure applying human body model electrostatic discharge (ESD) stress, the origin of dielectric breakdown in Cu/low-κ interconnect systems was found to be in interfacial delamination. The interfacial delamination between a SiC capping layer and a SiOC interdielectric layer is responsible for the increase of intermetal dielectric leakage current, causing high current Joule heating as well as catastrophic thermal breakdown. Also, the defect density increased as the delamination becomes wider while the number of ESD zaps increases.

KW - Delamination

KW - Dielectric breakdown

KW - Interconnect

KW - Leakage current

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JO - IEEE Electron Device Letters

JF - IEEE Electron Device Letters

IS - 4

ER -

Investigation of intrinsic dielectric breakdown mechanism in Cu/low-κ interconnect system

Abstract

ASJC Scopus Subject Areas

Keywords

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