Substrate-Influenced Thermo-Mechanical Fatigue of Copper Metallizations: Limits of Stoney's equation

Stephan Bigl; Stefan Wurster; Megan J. Cordill; Daniel Kiener

doi:10.3390/ma10111287

Substrate-Influenced Thermo-Mechanical Fatigue of Copper Metallizations: Limits of Stoney's equation

Stephan Bigl
, Stefan Wurster
, Megan J. Cordill
, Daniel Kiener

Lehrstuhl für Materialphysik (430)

Erich-Schmid-Institut für Materialwissenschaft der Österreichischen Akademie der Wissenschaften

Publikation: Beitrag in Fachzeitschrift › Artikel › Forschung › Begutachtung

3 Zitate (Scopus)

Abstract

Rapid progress in the reduction of substrate thickness for silicon-based microelectronics leads to a significant reduction of the device bending stiffness and the need to address its implication for the thermo-mechanical fatigue behavior of metallization layers. Results on 5 µm thick Cu films reveal a strong substrate thickness-dependent microstructural evolution. Substrates with hs = 323 and 220 µm showed that the Cu microstructure exhibits accelerated grain growth and surface roughening. Moreover, curvature-strain data indicates that Stoney’s simplified curvature-stress relation is not valid for thin substrates with regard to the expected strains, but can be addressed using more sophisticated plate bending theories.

Originalsprache	Englisch
Aufsatznummer	1287
Seitenumfang	8
Fachzeitschrift	Materials
Jahrgang	10.2017
Ausgabenummer	11
DOIs	https://doi.org/10.3390/ma10111287
Publikationsstatus	Veröffentlicht - 9 Nov. 2017

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10.3390/ma10111287

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title = "Substrate-Influenced Thermo-Mechanical Fatigue of Copper Metallizations: Limits of Stoney's equation",

abstract = "Rapid progress in the reduction of substrate thickness for silicon-based microelectronics leads to a significant reduction of the device bending stiffness and the need to address its implication for the thermo-mechanical fatigue behavior of metallization layers. Results on 5 µm thick Cu films reveal a strong substrate thickness-dependent microstructural evolution. Substrates with hs = 323 and 220 µm showed that the Cu microstructure exhibits accelerated grain growth and surface roughening. Moreover, curvature-strain data indicates that Stoney{\textquoteright}s simplified curvature-stress relation is not valid for thin substrates with regard to the expected strains, but can be addressed using more sophisticated plate bending theories.",

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author = "Stephan Bigl and Stefan Wurster and Cordill, \{Megan J.\} and Daniel Kiener",

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AU - Cordill, Megan J.

AU - Kiener, Daniel

PY - 2017/11/9

Y1 - 2017/11/9

N2 - Rapid progress in the reduction of substrate thickness for silicon-based microelectronics leads to a significant reduction of the device bending stiffness and the need to address its implication for the thermo-mechanical fatigue behavior of metallization layers. Results on 5 µm thick Cu films reveal a strong substrate thickness-dependent microstructural evolution. Substrates with hs = 323 and 220 µm showed that the Cu microstructure exhibits accelerated grain growth and surface roughening. Moreover, curvature-strain data indicates that Stoney’s simplified curvature-stress relation is not valid for thin substrates with regard to the expected strains, but can be addressed using more sophisticated plate bending theories.

AB - Rapid progress in the reduction of substrate thickness for silicon-based microelectronics leads to a significant reduction of the device bending stiffness and the need to address its implication for the thermo-mechanical fatigue behavior of metallization layers. Results on 5 µm thick Cu films reveal a strong substrate thickness-dependent microstructural evolution. Substrates with hs = 323 and 220 µm showed that the Cu microstructure exhibits accelerated grain growth and surface roughening. Moreover, curvature-strain data indicates that Stoney’s simplified curvature-stress relation is not valid for thin substrates with regard to the expected strains, but can be addressed using more sophisticated plate bending theories.

KW - Stress

KW - Thermo-mechanical

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