Title :
Suppression of reverse short channel effect by a buried carbon layer
Author :
Gossmann, H.-J. ; Rafferty, C.S. ; Hobler, G. ; Vuong, H.-H. ; Jacobson, D.C. ; Frei, M.
Author_Institution :
Bell Labs., Lucent Technol., Murray Hill, NJ, USA
Abstract :
Transient diffusion in epitaxial silicon can be suppressed by incorporating high concentrations of carbon. However, the presence of carbon at this level inside the depletion regions of a device leads to increased leakage. We show that a carbon profile tailored to give reduction of transient diffusion (TED) while minimizing carbon concentration in the depletion layer avoids the problems associated with carbon while maintaining the advantages. Such a profile can be achieved by ion implantation. Before C is able to reduce TED a high temperature annealing step is required that removes the C-implant damage. SIMS measurements verify that the expected reduction in transient diffusion occurred, while NMOS devices fabricated with a buried carbon layer have no RSCE and a shift in threshold voltage indicating suppression of TED. The impact on device leakage is minimal.
Keywords :
MOSFET; annealing; buried layers; carbon; chemical interdiffusion; doping profiles; ion implantation; semiconductor epitaxial layers; C-implant damage removal; NMOS devices; SIMS measurements; Si:C; buried C layer; depletion layer; device leakage; epitaxial Si; high temperature annealing step; ion implantation; reverse short channel effect suppression; tailored C profile; threshold voltage shift; transient diffusion suppression; Annealing; Implants; Impurities; Ion implantation; Jacobian matrices; MOS devices; Silicon; Temperature; Threshold voltage; Virtual manufacturing;
Conference_Titel :
Electron Devices Meeting, 1998. IEDM '98. Technical Digest., International
Conference_Location :
San Francisco, CA, USA
Print_ISBN :
0-7803-4774-9
DOI :
10.1109/IEDM.1998.746459
