Title :
Vacancy engineering for highly activated ‘diffusionless’ boron doping in bulk silicon
Author :
Bennett, N.S. ; Cowern, N.E.B. ; Paul, S. ; Lerch, W. ; Kheyrandish, H. ; Smith, A.J. ; Gwilliam, R. ; Sealy, B.J.
Author_Institution :
Sch. of Electr., Electron. & Comput. Eng, Newcastle Univ., Newcastle upon Tyne
Abstract :
Simulation and physical experiments have shown that vacancy engineering implants have the potential to provide outstanding pMOS source/drain performance for several future CMOS device generations. Using vacancy-generating implants prior to boron implantation, hole concentrations approaching 1021cm-3 can be achieved using low thermal budget annealing. In this new study we propose that the vacancy engineering technique is not reliant on the implementation of SOI-based CMOS but is also directly applicable to bulk silicon technologies.
Keywords :
MOS integrated circuits; annealing; boron; elemental semiconductors; hole density; ion implantation; semiconductor doping; silicon; vacancies (crystal); Si:B; boron implantation; bulk silicon; diffusionless boron doping; hole concentrations; low thermal budget annealing; pMOS source-drain performance; vacancy engineering; vacancy-generating implants; Annealing; Boron; CMOS technology; Doping; Implants; Power engineering and energy; Silicon on insulator technology; Solid lasers; Substrates; Temperature;
Conference_Titel :
Solid-State Device Research Conference, 2008. ESSDERC 2008. 38th European
Conference_Location :
Edinburgh
Print_ISBN :
978-1-4244-2363-7
Electronic_ISBN :
1930-8876
DOI :
10.1109/ESSDERC.2008.4681755
