We have developed a massive on-cell overlay metrology system based on Mueller matrix measurements. By integrating microscopic techniques into ellipsometry, we achieved high-throughput and extensive sampling coverage, with 1-shot/field per 1-field of view (FOV) measurement capability within a 34 x 34 mm2 FOV. Analyzing the off-diagonal components of the Mueller matrix allowed for on-cell overlay measurement across the wafer. This system provides measurement sensitivity comparable to e-beam-based technologies while offering high coverage, enabling precise reticle correction or high-order overlay correction in photolithography processes. This advancement represents a significant improvement in overlay metrology, offering both sensitivity and resolution for enhanced semiconductor manufacturing processes.
In recent years, the overlay specifications of advanced semiconductor devices have become extremely stringent. This challenging situation becomes severe for every new generation of the device development. However, conventional overlay metrology systems have limited throughput due to their point-based nature. Here, we first demonstrate the novel imaging Mueller-matrix spectroscopic ellipsometry (MMSE) technique, which can measure the overlay error of all cell blocks on a device wafer with extremely high throughput, much faster than conventional point-based spectroscopic ellipsometry (SE) technologies. It provides the super large field of view (FOV) ~ 20 × 20 mm2 together with high sensitivity based on Mueller information, which will be truly innovated solution not only for the overlay metrology, but also for critical dimension (CD) measurement, eventually maximizing process control and productivity of advanced node.
In this paper, we propose an unique metrology technique for the measurement of three-dimensional (3D) nanoscale structures of semiconductor devices, employing imaging-based massive Mueller-matrix spectroscopic ellipsometry (MMSE) with ultra-wide field of view (FOV) of 20×20 mm2. The proposed system enables rapid measurement of 10 million critical dimension (CD) values from all pixels in the image, while the conventional point-based metrology technique only measures a single CD value. We obtain Mueller matrix (MM) spectrum by manipulating wavelength and polarization states using a custom designed optical setup, and show that the proposed method characterizes complex 3D structures of the semiconductor device. We experimentally demonstrate CD measurement performance and consistency in the extremely large FOV, and suggest that the combination of MMSE and massive measurement capability can provide valuable insights: fingerprints originated from the manufacturing process, which are not easily obtained with conventional techniques.
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