| abstract |
A coplanar CMOS process for fabricating self-aligned gate FETs utilizing high energy, high dose rate ion implants to form the S/D regions. In the course of coplanar processing, the gate electrodes and S/D regions are defined. Selectively prescribed thicknesses of silicon dioxide are then formed over the top and sidewalls of the gate electrodes, as well as the exposed substrate in the S/D regions. Thereafter, a first, silicon nitride layer of controlled thickness is evenly deposited, and is followed by a dry etch step to expose the thin layer of silicon dioxide covering the p-channel FET S/D regions. The temperature stability of silicon nitride protects the n-channel FETs from the effects of the high energy levels and currents associated with the ion implant step used to form the S/D regions of the p-channel FETs. In contrast, the implant ions readily penetrate the thin oxides over the S/D regions of the p-channel FETs. Thereafter, a second, silicon nitride layer of controlled thickness is deposited. Again, it is followed by a dry etch step, but now to expose the silicon dioxide covering the n-channel FET S/D regions. The succeeding n-channel S/D implant similarly penetrates the silicon dioxide coverings, while the silicon nitride serves as a barrier for the remaining substrate surface. After S/D implanting is completed, a highly preferential etchant is used to remove the remaining silicon nitride, while the areas protected by the relatively thin layers of silicon dioxide are substantially unaffected. |