Comprehensive defect avoidance framework for mitigating extreme ultraviolet mask defects

Abstract. Defect avoidance methods are likely to play a key role in overcoming the challenge of mask blank defectivity in extreme ultraviolet (EUV) lithography. In this work, we propose an innovative EUV mask defect avoidance method. It is the first approach that allows exploring all the degrees of freedom available for defect avoidance (pattern shift, rotation and mask floorplanning). We model the defect avoidance problem as a global, nonconvex optimization problem and then solve it using a combination of random walk and gradient descent. For a 8-nm polysilicon layer of an ARM Cortex M0 layout, our method achieves a 60% point better mask yield compared to prior art in defect avoidance for a 40-defect mask. We show that pattern shift is the most significant degree of freedom for improving mask yield. Rotation and mask floorplanning can also help improve mask yield to a certain extent.

[1]  John Burns,et al.  EUV mask defect mitigation through pattern placement , 2010, Photomask Technology.

[2]  Puneet Gupta,et al.  Yield Analysis and Optimization , 2008, Handbook of Algorithms for Physical Design Automation.

[3]  Puneet Gupta,et al.  Design-Aware Mask Inspection , 2010, IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems.

[4]  Pei-Yang Yan,et al.  EUVL multilayer mask blank defect mitigation for defect-free EUVL mask fabrication , 2012, Advanced Lithography.

[5]  Yuelin Du,et al.  Layout small-angle rotation and shift for EUV defect mitigation , 2012, 2012 IEEE/ACM International Conference on Computer-Aided Design (ICCAD).

[6]  Chris Clifford Simulation and compensation methods for EUV lithography masks with buried defects , 2010 .

[7]  Jon Louis Bentley,et al.  Multidimensional binary search trees used for associative searching , 1975, CACM.

[8]  V. Bakshi EUV Lithography , 2008 .

[9]  A. Wagner,et al.  Mitigation of extreme ultraviolet mask defects by pattern shifting: Method and statistics , 2012 .

[10]  H. Levinson Extreme ultraviolet lithography’s path to manufacturing , 2009 .

[11]  Hongbo Zhang,et al.  EUV mask preparation considering blank defects mitigation , 2011, Photomask Technology.

[12]  Naveed A. Sherwani,et al.  Algorithms for VLSI Physical Design Automation , 1999, Springer US.

[13]  Hongbo Zhang,et al.  Efficient multi-die placement for blank defect mitigation in EUV lithography , 2012, Advanced Lithography.

[14]  Andrew B. Kahng,et al.  Cost-driven mask strategies considering parametric yield, defectivity, and production volume , 2011 .

[15]  A. A. Kagalwalla,et al.  Design-Aware Defect-Avoidance Floorplanning of EUV Masks , 2013, IEEE Transactions on Semiconductor Manufacturing.

[16]  Hongbo Zhang,et al.  Linear time EUV blank defect mitigation algorithm considering tolerance to inspection inaccuracy , 2012, Photomask Technology.

[17]  Eric Hendrickx,et al.  Evidence of printing blank-related defects on EUV masks missed by blank inspection , 2011, European Mask and Lithography Conference.

[18]  裕幸 飯田,et al.  International Technology Roadmap for Semiconductors 2003の要求清浄度について - シリコンウエハ表面と雰囲気環境に要求される清浄度, 分析方法の現状について - , 2004 .

[19]  Ahmad Elayat,et al.  EUV mask-blank defect avoidance solutions assessment , 2012, Photomask Technology.

[20]  Yuelin Du,et al.  Efficient pattern relocation for EUV blank defect mitigation , 2012, 17th Asia and South Pacific Design Automation Conference.

[21]  Andrew R. Neureuther,et al.  Performance of repaired defects and attPSM in EUV multilayer masks , 2002, Photomask Technology.

[22]  Emily Gallagher,et al.  Through-focus EUV multilayer defect repair with nanomachining , 2013, Advanced Lithography.

[23]  Puneet Gupta,et al.  EUV-CDA: Pattern shift aware critical density analysis for EUV mask layouts , 2014, 2014 19th Asia and South Pacific Design Automation Conference (ASP-DAC).

[24]  László Lovász,et al.  Hit-and-run mixes fast , 1999, Math. Program..