28 June 2013 Defect printability studies at SEMATECH
Author Affiliations +
Proceedings Volume 8701, Photomask and Next-Generation Lithography Mask Technology XX; 870111 (2013) https://doi.org/10.1117/12.2028069
Event: Photomask and NGL Mask Technology XX, 2013, Yokohama, Japan
Abstract
We describe SEMATECH’s recent defect printability work categorizing native phase defects by type and dimension using a NXE3100 EUV scanner and DPS (Defect Printability Simulator) software developed by Luminescent Technologies. Since the critical dimension (CD) error on a wafer simulated by the DPS is strongly affected by the multilayer (ML) geometry, it was very important to select the optimal multilayer (ML) growth model for each defect. By investigating the CD results obtained from 27 nm HP node imaging on NXE3100 and comparing those with simulation results, it was clear that reconstructed ML geometry generated by the AFM measurement showed much better simulation accuracy than conformal ML geometry. In order to find a typical ML growth model to predict the best ML geometry for a given dimension and height of defect, we calibrated a general ML growth model with AFM data and obtained ML growth model parameters. Using the fitted ML geometry generated from ML growth model parameters, CD error for 22 nm HP node was simulated and the result showed that conformal ML geometry is good for 24 nm defect simulation while not appropriate for 36 nm defect simulation.
© (2013) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE). Downloading of the abstract is permitted for personal use only.
Il-Yong Jang, Il-Yong Jang, Ranganath Teki, Ranganath Teki, Vibhu Jindal, Vibhu Jindal, Frank Goodwin, Frank Goodwin, Masaki Satake, Masaki Satake, Ying Li, Ying Li, Danping Peng, Danping Peng, Sungmin Huh, Sungmin Huh, Seong-Sue Kim, Seong-Sue Kim, } "Defect printability studies at SEMATECH", Proc. SPIE 8701, Photomask and Next-Generation Lithography Mask Technology XX, 870111 (28 June 2013); doi: 10.1117/12.2028069; https://doi.org/10.1117/12.2028069
PROCEEDINGS
11 PAGES


SHARE
RELATED CONTENT


Back to Top