Evaluating scatterometry 3D capabilities for EUV

Optical critical dimension (OCD) metrology using scatterometry has been demonstrated to be a viable solution for fast and non-destructive in-line process control and monitoring. As extreme ultraviolet lithography (EUVL) is more widely adopted to fabricate smaller and smaller patterns for electronic devices, scatterometry faces new challenges due to several reasons. For 14nm node and beyond, the feature size is nearly an order of magnitude smaller than the shortest wavelength used in scatterometry. In addition, thinner resist layer is used in EUVL compared with conventional lithography, which leads to reduced measurement sensitivity. Despite these difficulties, tolerance has reduced for smaller feature size. In this work we evaluate 3D capability of scatterometry for EUV process using spectroscopic ellipsometry (SE). Three types of structures, contact holes, tip-to-tip, and tip-to-edge, are studied to test CD and end-gap metrology capabilities. The wafer is processed with focus and exposure matrix. Good correlations to CD-SEM results are achieved and good dynamic precision is obtained for all the key parameters. In addition, the fit to process provides an independent method to evaluate data quality from different metrology tools such as OCD and CDSEM. We demonstrate 3D capabilities of scatterometry OCD metrology for EUVL using spectroscopic ellipsometry, which provides valuable in-line metrology for CD and end-gap control in electronic circuit fabrications.

[1]  Yongdong Liu,et al.  Mueller matrix measurement of asymmetric gratings , 2010 .

[2]  John Arnold,et al.  Integration of EUV lithography in the fabrication of 22-nm node devices , 2009, Advanced Lithography.

[3]  Jie Li,et al.  Scatterometry evaluation of focus-dose effects of EUV structures , 2013, Advanced Lithography.

[4]  Clemens Utzny When things go pear shaped: contour variations of contacts , 2013, Advanced Lithography.

[5]  Lifeng Li,et al.  New formulation of the Fourier modal method for crossed surface-relief gratings , 1997 .

[6]  Hiroki Kawada,et al.  Robust edge detection with considering three-dimensional sidewall feature by CD-SEM , 2011, Advanced Lithography.

[7]  Alok Vaid,et al.  Lithography process control using scatterometry metrology and semi-physical modeling , 2007, SPIE Advanced Lithography.

[8]  Jiangtao Hu,et al.  Uncertainty and sensitivity analysis and its applications in OCD measurements , 2009, Advanced Lithography.

[9]  Keith A. Woodbury,et al.  Inverse problems and parameter estimation: integration of measurements and analysis , 1998 .

[10]  John Arnold,et al.  The use of EUV lithography to produce demonstration devices , 2008, SPIE Advanced Lithography.

[11]  Pei-yang Yan,et al.  Understanding Bossung curve asymmetry and focus shift effect in EUV lithography , 2002, SPIE Photomask Technology.

[12]  Philippe Hurat,et al.  Electrical design for manufacturability and lithography and stress variability hotspot detection flows at 28nmn , 2012, Advanced Lithography.