Title :
Threshold-voltage anomaly in sub-0.2 μm DRAM buried-channel pFET devices
Author :
Murthy, C.S. ; Katsumata, R. ; Inaba, S. ; Rengarajan, R. ; Oldiges, P. ; Ronsheim, P.
Author_Institution :
IBM Semicond. R&D Center, Hopewell Junction, NY, USA
Abstract :
Measurements and simulation have been used to study threshold-voltage (Vt) dependence on gate oxide thickness (t ox) for long-channel buried-channel (BC-) pFET devices in sub-0.2 μm CMOS technologies. The combination of the dual gate oxide process using N2 implantation to create the thinner gate oxide and well RTA results in the thinner tox devices having higher Vt, contrary to expectation (Vt-tox anomaly). Detailed analysis of doping profiles, depletion contours, and electric potential confirms this anomaly both in the enhancement and depletion modes of operation. These studies show that a balance of net doping between that near the surface and that around the BC-layer is a stringent requirement for the Vt control in BC-pFETS
Keywords :
DRAM chips; MOSFET; buried layers; doping profiles; ion implantation; rapid thermal annealing; 0.2 micron; CMOS technology; DRAM; N2 implantation; depletion layer; depletion mode; doping profile; dual gate oxide process; electric potential; enhancement mode; gate oxide thickness; long-channel buried-channel pFET device; rapid thermal annealing; threshold voltage; Charge carrier processes; Doping profiles; Electric potential; Equations; Implants; Joining processes; Neodymium; Potential well; Random access memory;
Conference_Titel :
VLSI Technology, Systems, and Applications, 2001. Proceedings of Technical Papers. 2001 International Symposium on
Conference_Location :
Hsinchu
Print_ISBN :
0-7803-6412-0
DOI :
10.1109/VTSA.2001.934471
