Abstract :
In this paper, we analyze the nonuniformity of sliding distance on both the wafer and polishing pad from a kinematic point of view. Using the Fourier series expansion, it can be shown that in steady state the nonuniformity caused by contact relative velocity is determined by rotational speed ratio between platen and wafer carrier (m) and the ratio of wafer radius to the distance between the platen center and wafer center (Rc/d). In general, the nonuniformity of wafer increases with |m| and (Rc/d). An important observation for the polishing pad is that in two particular ranges of the ratio m, larger (Rc/d) on the contrary yields smaller nonuniformity. Then, a ring-type polishing pad is proposed for the purpose of improving the nonuniformity of both wafer and pad. However, it turns out the result for the pad of large size is worse than the traditional shape, unless the rotational speed of the pad is much slower than that of the wafer.
Keywords :
Fourier series; chemical mechanical polishing; Fourier series expansion; chemical mechanical planarisation; chemical mechanical polishing; kinematic aspects; pad nonuniformity; sliding distance nonuniformity; wafer nonuniformity; Chemistry; Equations; Fourier series; Kinematics; Planarization; Position measurement; Semiconductor materials; Slurries; Steady-state; Velocity measurement; Chemical–mechanical polishing (CMP); Preston equation; nonuniformity; ring-type polishing pad; sliding distance;
