A high-performance half-micrometer generation CMOS technology for fast SRAMs

Abstract

An advanced, high-performance, half-micrometer generation technology has been developed for fast CMOS SRAM circuits. This process features an aggressive interwell isolation module which allows scaling of the n/sup +/ to p/sup +/ space to less than 2 mu m and an advanced framed-mask poly-buffered LOCOS isolation (FMPBL) which reduces field oxide encroachment and the transistor narrow-width effect and provides a 1.2- mu m active pitch. Transistors are fabricated with a 125-A gate oxide and a dual n/sup +//p/sup +/ source/drain implanted polysilicon gates to provide excellent short-channel behavior down to 0.3- mu m effective channel length. Transistor design is optimized to reduce the polysilicon gate bird's beak and lightly doped drain (LDD) underdiffusion. For PMOS transistors, boron diffusion through the gate oxide is minimized by replacing BF/sub 2/ with B/sup 11/ for the p/sup +/ S/D implant. A titanium salicide process provides strapping between n/sup +//p/sup +/ polysilicon gates and lower sheet and contact resistances. The back-end features three levels of metallization and polysilicon contact plugs. Discrete transistor lifetimes for DC hot-carrier degradation are in excess of 10 years at 3.3-V operation. A 16 K* 4 SRAM displayed no parametric shifts after hot-carrier stressing for 1000 h at 7-V and 0 degrees C. This is consistent with a lifetime of greater than 10 years at 3.3-V operation. Ring oscillator delay times of 85 ps at 3.3-V and 65 ps at 5-V supply are achieved.< <ETX xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">&gt;</ETX>