Approach to full-chip simulation and correction of stencil mask distortion for proximity electron lithographyWe have devised a new mask format for low-energy electron-beam proximity-projection lithography ͑LEEPL͒ that enables faster and more accurate image transfer from the mask to a wafer, in comparison with the single-membrane mask as originally proposed. Simultaneous exposure over four adjacent complementary quadrants of the mask, synchronized with step-and-repeat motion of the wafer stage, yields one complete pattern with the throughput of ϳ30 wafers/h. Mechanical analysis has demonstrated that the new format also offers better controllability of image placement owing to smaller membranes, even though the gravitational deformation of the mask, for example, must still be corrected for.
In order to solve the various problems associated with a LEEPL mask as originally demonstrated in the form of single-membrane diamond mask, we propose a new mask format termed COSMOS (complementary stencil mask on strut-supports). The COSMOS has small-area membranes with strut reinforcement and is somewhat similar to the masks used for other types of electron projection lithography (EPL). However, the exposure strategy is completely different from the other EPLs; a complete pattern image can be transcribed by overlaying complementary portions of a mask pattern via multiple exposures. The inter-membrane and intra-membrane distortions of image placement have been computed by the finite element method (FEM) simulation. It is concluded that the global distortion induced by the inversion of gravity can be corrected for by mask writing, and the intra-membrane distortion, induced by both the gravitational flexure of a membrane and the pattern density distribution, can be neglected with the membrane intrinsic stress of approximately 5 MPa.
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