Translator Disclaimer
12 June 2003 Resist reflow for 193-nm low-K1 lithography contacts
Author Affiliations +
Abstract
Contact patterning for advanced lithography generations is increasingly being viewed as a major threat to the continuation of Moore's Law. There are no easy patterning strategies which enable dense through isolated contacts of very small size. Lack of isolated contact focus latitude, high dense contact mask error factor and incredibly low defectivity rate requirements are severe issues to overcome. These difficulties mean that new and complex patterning methods for contacts at the 90nm and 65nm device generations are being considered. One possible option for improving the process window of contact patterning is resist reflow. Resist reflow can supplement almost any other optical extension method for contact lithography. Previous results have shown the significant benefits of this method for CD control on semi-dense and isolated contact for the 100nm device generation. This work extends the previous work by investigating very dense pitch through isolated contact patterning at 193nm low K1 lithography regimes. The encouraging overall CD control and process window of reflowed contacts using the ARCH TIS2000 bilayer resist system is analyzed through pitch for different imaging options. An investigation of the capability of resist reflow in combination with optimized reticle and illumination for the 65nm device generation is also presented as are details of defectivity levels for reflowed contacts on 90nm device products.
© (2003) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE). Downloading of the abstract is permitted for personal use only.
Patrick K. Montgomery, Kevin Lucas, Kirk J. Strozewski, Lena Zavyalova, Grozdan Grozev, Mario Reybrouck, Plamen Tzviatkov, and Mireille Maenhoudt "Resist reflow for 193-nm low-K1 lithography contacts", Proc. SPIE 5039, Advances in Resist Technology and Processing XX, (12 June 2003); https://doi.org/10.1117/12.485186
PROCEEDINGS
10 PAGES


SHARE
Advertisement
Advertisement
Back to Top