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The Effect of Collimation On Sputtered Alcusi and Almg Microstructures And Electromigration Failure Characteristics

Published online by Cambridge University Press:  21 February 2011

Thomas J. Licata ,
Timothy D. Sullivan ,
Roy S. Bass ,
James G. Ryan  and
David B. Knorr
Thomas J. Licata
Affiliation:
IBM Technology Products: Hopewell Junction, NY 12533
Timothy D. Sullivan
Affiliation:
Essex Junction, VT 05452
Roy S. Bass
Affiliation:
Rensselaer Polytechnic Institute, Department of Materials Science, Troy, NY 12180
James G. Ryan
Affiliation:
IBM Technology Products: Hopewell Junction, NY 12533
David B. Knorr
Affiliation:
IBM Technology Products: Hopewell Junction, NY 12533
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Abstract

Increasing circuit densities produce higher metal wiring aspect ratios, and more difficult feature fill for damascene processing. One method of extending the use of sputter deposition to challenging aspect ratios is to collimate the sputtered flux using a collimator plate, and to avoid randomizing the collimated flux by using low process pressures corresponding to long sputtered atom mean free paths. In this paper, we discuss our fabrication of damascene AI-0.5Cu-2Si and AI-2Mg wiring using both collimated and uncollimated sputtering, and our observations of collimation-induced changes in Al alloy electromigration and microstructure. Our experiments show that collimation has only a small effect on AlCuSi, but a large effect on AIMg. Specifically, the median time to electromigration failure for collimated AIMg was ∼10X the value for uncollimated AlMg and ∼6X the values for collimated and uncollimated AlCuSi. Transmission electron microscope and x-ray diffraction analyses of these films show that the collimation-induced improvement in AIMg t50 is associated with the formation of smaller, lower strain grains which are clustered in very well-oriented (111) domains. We propose that the advantageous AlMg microstructure results from enhanced texture produced by aspects of the collimated deposition active in the absence of incoherent precipitates.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 309: Symposium M2 – Materials Reliability in Microelectronics III , 1993 , 87
Copyright
Copyright © Materials Research Society 1993

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