Yuji Chiba

New-generation projection optics for ArF lithography

We have developed an ArF scanner with 0.7NA, the FPA- 5000AS2, to meet the requirements of the semiconductor industry. The biggest improvement of this system from the previous model is its projection optics. The new projection lens design allows residual aberrations to be extremely small in order to satisfy the requirements of increasingly severe device production. Furthermore, the aberrations derived from the manufacturing process are minimized in the same manner as conventional i-line and KrF lenses by precisely measuring them with a phase measuring interferometer (PMI). To reduce manufacturing-induced aberrations, we calculate various components of imaging performance at each lens manufacturing process and feed them back to the tuning process. Focusing only on aberration in the expression of root mean square (RMS) can never be sufficient for optimal aberration reduction. Lens performance can be optimally improved by gaining a balance among Zernike terms, which represent aberrations, for critical dimensions of various device patterns. It helps us supply users with a projection lens having performance that meets their requirements. This paper reports on the imaging performance of the new lens for both static and dynamic exposure as well as simulation results using PMI data. It also presents the mechanical barrel system that holds the high performance projection lens, intrinsic birefringence (IBR) of CaF2, and leading-edge ArF lens technologies such as chemical clean technology. And imaging performance of the newest 0.75 NAArF projection lens is demonstrated.

Development status of a 157-nm full-field scanner

157 nm lithography has made further progress over the past year, steadily advancing towards the realization of the 65 nm era. In particular, exposure tools have moved on to the assembly phase, with new functions and performance now under evaluation. This paper presents our technical progress in our 157nm full field exposure tool, focusing on two key technologies: projection optics and environmental control with highly purified gasses. The high NA projection optics were designed to meet accelerating demands for smaller geometries. A catadioptric system with a line-selected laser was chosen to solve the problem of chromatic aberrations. The birefringence effect caused by CaF2 has been reduced to acceptable levels by clocking and combining <111> and <100> oriented crystals. Polishing and optical coatings consisting of glass materials were completed at targeted accuracy. At the present time, assembly and tuning of the projection optics is being performed. A simulation based on the inspection data from each production step predicts that the desired image performance will be attained. The total efficiency of the exposure system is expected to be higher than previously announced, due to the improvement of both CaF2 transmittance and AR/HR coatings. One of two keys issues in environmental control is to purge the projection optics which are permanently sealed. Purging performance was tested using a mockup of the projection optics. The second issue is to purge the areas around reticles and wafers which are continually carried into and out of the exposure system. Using the actual platform, the wafer and reticle purging performance was evaluated. It has been demonstrated that both of our purging systems are effective in keeping the environment at minimum contamination levels. This contributes to the increase of throughput.