Title :
Dose uniformity of sub-keV implants
Author :
Tandon, Sanjeev ; Al-Bayati, Amir
Author_Institution :
Transistor, Doping, and Junctions Div., Appl. Mater. Inc., Santa Clara, CA, USA
Abstract :
As device dimensions are reduced below 0.18 μm, low energy ion implantation will be increasingly used for the formation of ultra shallow junctions (<40 nm) required for source/drain extensions. As the ion energy is reduced the projected range decreases and becomes comparable to the native oxide thickness. Due to the proximity of ions to the surface, the sheet resistance uniformity becomes sensitive to the native oxide thickness variation and anneal conditions. In this paper we investigate the dependence of sheet resistance uniformity on ion energy, oxide thickness variation and anneal ambient conditions. Although the sheet resistance nonuniformity increases with decreasing energy we show that highly uniform R1 maps (<1.5% one sigma) can be obtained with ion energy down to 200 eV by the proper optimization of implant and anneal conditions and wafer surface preparation
Keywords :
arsenic; boron; elemental semiconductors; ion implantation; rapid thermal annealing; silicon; surface conductivity; 0.18 micron; 200 eV; 40 nm; O2; Si:As; Si:B; annealing conditions; ion implantation energy; low energy ion implantation; native oxide thickness variation; oxide thickness variation; sheet resistance uniformity; source/drain extensions; sub-keV implant dose uniformity; ultra shallow junctions; wafer surface preparation; Boron; Chemicals; Doping; Electrical resistance measurement; Implants; Ion implantation; Rapid thermal annealing; Surface resistance; Temperature sensors; Thickness measurement;
Conference_Titel :
Ion Implantation Technology, 2000. Conference on
Conference_Location :
Alpbach
Print_ISBN :
0-7803-6462-7
DOI :
10.1109/.2000.924239
