论文信息 - Wafer-shape metrics based foundry lithography

Wafer-shape metrics based foundry lithography

As device shrink, there are many difficulties with process integration and device yield. Lithography process control is expected to be a major challenge due to tighter overlay and focus control requirement. The understanding and control of stresses accumulated during device fabrication has becoming more critical at advanced technology nodes. Within-wafer stress variations cause local wafer distortions which in turn present challenges for managing overlay and depth of focus during lithography. A novel technique for measuring distortion is Coherent Gradient Sensing (CGS) interferometry, which is capable of generating a high-density distortion data set of the full wafer within a time frame suitable for a high volume manufacturing (HVM) environment. In this paper, we describe the adoption of CGS (Coherent Gradient Sensing) interferometry into high volume foundry manufacturing to overcome these challenges. Leveraging this high density 3D metrology, we characterized its In-plane distortion as well as its topography capabilities applied to the full flow of an advanced foundry manufacturing. Case studies are presented that summarize the use of CGS data to reveal correlations between in-plane distortion and overlay variation as well as between topography and device yield.

[1] Ares J. Rosakis,et al. Full Field Measurements of Curvature using Coherent Gradient Sensing: Application to Thin Film Characterization , 1997 .

[2] Ares J. Rosakis,et al. Thin film/substrate systems featuring arbitrary film thickness and misfit strain distributions. Part I: Analysis for obtaining film stress from non-local curvature information , 2007 .

[3] Nelson Felix,et al. Characterization of wafer geometry and overlay error on silicon wafers with nonuniform stress , 2013 .

[4] David M. Owen,et al. Characterization of deformation induced by micro-second laser anneal using CGS interferometry , 2008, 2008 16th IEEE International Conference on Advanced Thermal Processing of Semiconductors.

[5] G. Stoney. The Tension of Metallic Films Deposited by Electrolysis , 1909 .

[6] Subra Suresh,et al. Effects of line and passivation geometry on curvature evolution during processing and thermal cycling in copper interconnect lines , 2000 .

[7] David Laidler,et al. Wafer-shape based in-plane distortion predictions using superfast 4G metrology , 2017, Advanced Lithography.

[8] Doug Anberg,et al. A study of feed-forward strategies for overlay control in lithography processes using CGS technology , 2015, 2015 26th Annual SEMI Advanced Semiconductor Manufacturing Conference (ASMC).

[9] Chris A. Mack. Understanding Focus Effects In Submicron Optical Lithography , 1988, Advanced Lithography.