Boron diffusion and activation in polysilicon multilayer films for P+ MOS structure: Characterization and modeling

“…Two related processes limit the realization of this goal: (i) the enhanced redistribution of the B during the thermal dopant‐activation annealing, which causes B penetration through thin oxides from the p + poly‐Si gate into the underlying layers 3, and (ii) the formation of electrically inactive B clusters and B precipitates 4,5, which decreases the dopant activation rate. The use of low‐energy doping methods, co‐doping techniques, low thermal annealing temperatures, short annealing times, amorphous‐silicon layers, and thin Nitrogen‐Doped‐Silicon (NiDoS) layers have been practiced to avoid the doping depletion of p + polysilicon gate at the oxide interface 6–8. Currently, significant research efforts are focused on improving the B activation and reducing fast B diffusion behaviour; problem common to all the practiced methods and technics.…”

Complex boron redistribution kinetics in strongly doped polycrystalline‐silicon/nitrogen‐doped‐silicon thin bi‐layers

“…Two related processes limit the realization of this goal: (i) the enhanced redistribution of the B during the thermal dopant‐activation annealing, which causes B penetration through thin oxides from the p + poly‐Si gate into the underlying layers 3, and (ii) the formation of electrically inactive B clusters and B precipitates 4,5, which decreases the dopant activation rate. The use of low‐energy doping methods, co‐doping techniques, low thermal annealing temperatures, short annealing times, amorphous‐silicon layers, and thin Nitrogen‐Doped‐Silicon (NiDoS) layers have been practiced to avoid the doping depletion of p + polysilicon gate at the oxide interface 6–8. Currently, significant research efforts are focused on improving the B activation and reducing fast B diffusion behaviour; problem common to all the practiced methods and technics.…”

Complex boron redistribution kinetics in strongly doped polycrystalline‐silicon/nitrogen‐doped‐silicon thin bi‐layers

“…Several solutions have been proposed in MOS structure such as replacing the Si oxide layer by high dielectric permittivity materials, [8][9][10] varying the elaboration method, the doping techniques and thermal annealing [11][12][13] or using multilayer gate transistors. 14) In a previous work, we studied the influence of low temperature annealing durations on B diffusion in multilayer B-doped polycrystalline silicon (poly-Si) (poly1)/undoped amorphous silicon (a-Si) (poly2)/Si oxide (SiO 2 ) deposited by LPCVD. 14) We showed that the B diffusion depths are small enough not to reach the poly2/ oxide interface at annealing temperature bellow 700 C. We also showed in another works that in-situ N-doped amorphous Si layers (NIDOS) are efficient B diffusion barriers.…”

“…14) In a previous work, we studied the influence of low temperature annealing durations on B diffusion in multilayer B-doped polycrystalline silicon (poly-Si) (poly1)/undoped amorphous silicon (a-Si) (poly2)/Si oxide (SiO 2 ) deposited by LPCVD. 14) We showed that the B diffusion depths are small enough not to reach the poly2/ oxide interface at annealing temperature bellow 700 C. We also showed in another works that in-situ N-doped amorphous Si layers (NIDOS) are efficient B diffusion barriers. 11,[15][16][17] Based on these results, we have studied a new multilayer structure, in which the undoped a-Si (poly2) is substituted by a NIDOS layer, to further reduce the B diffusion.…”

Study of Nitrogen Effect on the Boron Diffusion during Heat Treatment in Polycrystalline Silicon/Nitrogen-Doped Silicon Thin Films

Progress with passivation and screen-printed metallization of Boron-doped monoPoly™ layers