Title :
On the knocked oxygen contribution to low energy implanted boron diffusion retardation
Author :
Kaabi, L. ; AbdelMalek, F. ; Sassi, Z. ; Bureau, J.-C. ; Belhadj, W. ; Ballard, B.
Author_Institution :
Dept. de Genie Phys. et Instrum., Inst. Nat. des Sci. Appliques et de Technol., Tunis, Tunisia
Abstract :
Boron was implanted in crystalline silicon through oxide layers with different thicknesses. The implantation is carried out at various doses and energies of interest in Ultra Large Scale Integration (ULSI) applications. Rapid thermal annealings (RTA) are used in a way to obtain shallow junctions and electrical activation of the B atoms. However, transient enhanced diffusion induced by implantation damage can be observed on boron profiles before and after annealing obtained with secondary ion mass spectrometry (SIMS). It is found that the diffusion transient in the tail region of the boron profile increases with decreasing oxide thickness. Even more, if the implantation damage concerns mostly the oxide, i.e. when the concentration peak is located into this oxide, the oxygen knocked into the silicon substrate could play an important role in restricting the boron diffusion
Keywords :
boron; diffusion; doping profiles; elemental semiconductors; ion implantation; oxygen; rapid thermal annealing; secondary ion mass spectra; silicon; Si:B; Si:B-SiO2; concentration peak; crystalline silicon; diffusion transient; dose; electrical activation; implantation damage; knocked oxygen contribution; low energy implanted boron diffusion retardation; oxide layers; oxide thickness; secondary ion mass spectrometry; shallow junctions; Atomic layer deposition; Boron; Crystallization; Instruments; Oxygen; Rapid thermal annealing; Silicon; Substrates; Temperature distribution; Ultra large scale integration;
Conference_Titel :
Microtechnologies in Medicine and Biology, 1st Annual International, Conference On. 2000
Conference_Location :
Lyon
Print_ISBN :
0-7803-6603-4
DOI :
10.1109/MMB.2000.893806
