In-situ measurements of internal stresses in copper thin films during thermal cycling using synchrotron X-rays

In-situ measurements of internal stresses in copper thin films during thermal cycling using synchrotron X-rays

Using synchrotron X-rays at SPring-8, the internal stress in Cu thin films was measured in vacuum at various temperatures during heating and cooling cycle between room temperature and high temperature of 300 or 500/spl deg/C. Cu films with the thickness of 600 nm was sputtered on top of the under co...

Full description

Saved in:
Bibliographic Details
Published in:Micro-Nanomechatronics and Human Science, 2004 and The Fourth Symposium Micro-Nanomechatronics for Information-Based Society, 2004 pp. 69 - 73
Main Authors: Tanaka, K., Akiniwa, Y.
Format: Conference Proceeding
Language:English
Published: Piscataway NJ IEEE 2004
Subjects:
Copper
Exact sciences and technology
Instruments, apparatus, components and techniques common to several branches of physics and astronomy
Internal stresses
Mechanical instruments, equipment and techniques
Micromechanical devices and systems
Physics
Residual stresses
Stress measurement
Synchrotrons
Temperature
Tensile stress
Thermal stresses
Transistors
X-rays
Mechatronics
In situ
Cyclic loads
In situ test
Thermal load
Experimental study
Space heating
Thin films
Metal coating
Internal stresses
Synchrotrons
Copper
Microelectromechanical device
Synchrotron radiation
Stress measurement
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Using synchrotron X-rays at SPring-8, the internal stress in Cu thin films was measured in vacuum at various temperatures during heating and cooling cycle between room temperature and high temperature of 300 or 500/spl deg/C. Cu films with the thickness of 600 nm was sputtered on top of the under coating of TiN on Si wafer substrate. Cu thin films had a strong fiber texture with the fiber axis perpendicular to the film surface. The 311 diffraction was used for stress measurement. In the heating process, the tensile stress was decreased from 217 MPa to -115 MPa at 180/spl deg/C and then stress relaxation took place at higher temperatures. The stress diminished in the film at 500/spl deg/C. In the cooling process, the tensile stress was built up with decreasing temperature. After one heat cycle, the residual stress was increased from 217 to 367 MPa. The experimental results were compared with the theoretical prediction based on the method proposed by Thouless et al. A good agreement was obtained between experimental and theoretical results.
ISBN:0780386078
9780780386075
DOI:10.1109/MHS.2004.1421279