Title :
Optimizing p-type ultra-shallow junctions for the 65 nm CMOS technology node
Author :
Pawlak, B. ; Lindsay, R. ; Surdeanu, Radu ; Stolk, P. ; Maex, K. ; Pages, X.
Abstract :
The limits of using B or BF2 alone in forming ultrashallow junctions have been reached for the 90 nm CMOS generation. In this paper we evaluate the use of Ge and F co-implants to extend conventional implantation and spike anneal to the 65 nm CMOS technology node. In this work we show that the F co-implant can improve the abruptness of the B junction, while the single Ge usually degrades it. The use of Ge co-implanted with F gives the best junction abruptness - less than 5nm/decade. The best trade-off between junction depth (Xj) and sheet resistance (Rsheet) is achieved by deep Ge pre-amorphization and deep co-implantation of F. A comparison between slow and fast ramp-up is made. Significant improvement for the junction activation, its depth and abruptness is obtained by spike anneal with fast ramp-up for B junctions with Ge and F co-implantation.
Keywords :
CMOS integrated circuits; amorphisation; fluorine; germanium; ion implantation; rapid thermal annealing; semiconductor doping; 65 nm; 65 nm CMOS technology node; Ge/F co-implants; deep Ge pre-amorphization; deep co-implantation; junction depth; p-type ultra-shallow junctions optimisation; sheet resistance; spike anneal; Amorphous materials; Atomic layer deposition; Boron; CMOS technology; Degradation; Implants; Integrated circuit technology; Rapid thermal annealing; Solid lasers; Temperature;
Conference_Titel :
Ion Implantation Technology. 2002. Proceedings of the 14th International Conference on
Conference_Location :
Taos, New Mexico, USA
Print_ISBN :
0-7803-7155-0
DOI :
10.1109/IIT.2002.1257928
