Defect-aware process margin for chemo-epitaxial directed self-assembly lithography using simulation method based on self-consistent field theory

We proposed a new concept of “defect-aware process margin.” Defect-aware process margin was evaluated by investigating the energy difference between the free-energy of the most stable state and that of the first metastable state. The energy difference is strongly related to the defect density in DSA process. As a result of our rigorous simulations, the process margin of the pinning layer width was found to be: (1) worse when the pinning layer affinity is too large, (2) better when the background affinity has the opposite sign of the pinning layer affinity, and (3) better when the top of the background layer is higher than that of the pinning layer by 0.1L0.

[1]  G. Fredrickson,et al.  Defectivity in Laterally Confined Lamella-Forming Diblock Copolymers: Thermodynamic and Kinetic Aspects , 2012 .

[2]  He Yi,et al.  Exploration of the directed self-assembly based nano-fabrication design space using computational simulations , 2013, Advanced Lithography.

[3]  Glenn H. Fredrickson,et al.  Defectivity study of directed self-assembly of cylindrical diblock copolymers in laterally confined thin channels , 2013, Advanced Lithography.

[4]  Azat Latypov,et al.  Computational solution of inverse directed self-assembly problem , 2013, Advanced Lithography.

[5]  Kris T. Delaney,et al.  The hole shrink problem: Theoretical studies of directed self-assembly in cylindrical confinement , 2013, Advanced Lithography.

[6]  Takashi Taniguchi,et al.  Large-scale dynamics of directed self-assembly defects on chemically pre-patterned surface , 2013, Advanced Lithography.

[7]  Shoji Mimotogi,et al.  Novel error mode analysis method for graphoepitaxial directed self-assembly lithography based on the dissipative particle dynamics method , 2013, Advanced Lithography.

[8]  Makoto Muramatsu,et al.  Dissipative particle dynamics study on directed self-assembly in holes , 2013, Advanced Lithography.

[9]  Juan J. de Pablo,et al.  Chemical Patterns for Directed Self-Assembly of Lamellae-Forming Block Copolymers with Density Multiplication of Features , 2013 .

[10]  Katsuyoshi Kodera,et al.  Dissipative particle dynamics simulations to optimize contact hole shrink process using graphoepitaxial directed self-assembly , 2013, Advanced Lithography.

[11]  Neal Lafferty,et al.  Computational aspects of optical lithography extension by directed self-assembly , 2013, Advanced Lithography.

[12]  H.-S. Philip Wong,et al.  Computational simulation of block copolymer directed self-assembly in small topographical guiding templates , 2013, Advanced Lithography.