Lens heating impact analysis and controls for critical device layers by computational method

We report that, based on our experimental data, lens heating (LH) impact on wafer image can be effectively controlled by using a computational method (cASCAL) on critical device layers with no request on tool time. As design rule shrinks down, LH control plays a key role in preventing the image deterioration caused by the LH-induced wavefront distortion during exposure. To improve LH prediction accuracy, 3-dimension structure of mask stack (M3D) is considered in calculating the electro-magnetic (EM) field that passes through the mask for full chip. Additionally, lens specific calibration (LSC) is performed on individual scanners to take the lens-to-lens variation into account. In data comparisons, we show that cASCAL performs very well as an ASCAL substitute, and that M3D and LSC improve the LH prediction accuracy of cASCAL.