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Proceedings Paper

Measuring height variation over entire wafer surface with high lateral resolution
Author(s): Shouhong Tang; Brian Clendenin
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Paper Abstract

As the semiconductor industry progresses down the roadmap to smaller device geometries, precise metrology of the wafer nanotopography is increasingly needed by the wafer manufacturers and the semiconductor device manufacturers. To meet the demands, we have built an instrument that integrates our patented and proprietary white light interferometer with a motorized x-y stage. It measures height variation over the entire 200mm or 300mm wafer front surface with high lateral resolution and sub-nanometer height precision. This is accomplished by stitching together multiple maps obtained from a white light interferometer. Each individual map represents height variation over a part of the wafer surface. These individual maps are properly positioned to cover the entire wafer surface with sufficient overlapping area. With such properly arranged maps, we are able to produce an entire wafer surface by stitching them together. The map stitching expands the field of view available to our patented low coherence interferometer. This approach makes it possible to reveal more detail nanotopographic information over the entire wafer surface. In this paper, we will present the map stitching approach for the measurements of 200mm and 300mm wafers, including the theoretical foundations of stitching technique and the arrangements of individual measurements. We will also demonstrate measurement results on various wafers.

Paper Details

Date Published: 10 September 2007
PDF: 7 pages
Proc. SPIE 6672, Advanced Characterization Techniques for Optics, Semiconductors, and Nanotechnologies III, 667209 (10 September 2007); doi: 10.1117/12.735141
Show Author Affiliations
Shouhong Tang, KLA-Tencor (United States)
Brian Clendenin, KLA-Tencor (United States)

Published in SPIE Proceedings Vol. 6672:
Advanced Characterization Techniques for Optics, Semiconductors, and Nanotechnologies III
Angela Duparré; Bhanwar Singh; Zu-Han Gu, Editor(s)

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