Title :
High performance sub-half micron CMOS using rapid thermal processing
Author :
Chapman, R.A. ; Kuehne, J.W. ; Ying, P.S.-H. ; Richardson, W.F. ; Paterson, A.R. ; Lane, A.P. ; Chen, I.-C. ; Velo, L. ; Blanton, C.H. ; Mosiehl, M.M. ; Paterson, J.L.
Author_Institution :
Texas Instruments Inc., Dallas, TX, USA
Abstract :
A sub-half micron CMOS technology has been developed using rapid thermal processing (RTP) and a simplified process design. The threshold voltages are set high to permit operation above room temperature without excessive leakage. Novel process features include zero-topography well design, RTP CMOS well anneal in an ammonia ambient, RTP gate oxide, RTP source/drain anneal, and BPSG reflow at 750 degrees C in a high-pressure nitrogen ambient. Transistors with 8 nm gate oxide and 0.4 mu m gate lengths provide 65 ps gate delay at 3.3 V. The use of 4*10/sup 17//cm/sup 3/ CMOS well doping without added channel implants results in higher diode capacitance and increases inverter chain delay by approximately 20 ps/stage, but speeds less than 50 ps/stage should be obtained with L=0.3 mu m NMOS and L=0.4 mu m PMOS, both having effective channel lengths of approximately 0.2 mu m.<>
Keywords :
CMOS integrated circuits; integrated circuit technology; rapid thermal processing; 0.2 to 0.4 micron; 20 to 65 ps; 3.3 V; 750 degC; B2O3-P2O5-SiO2; BPSG reflow; NH/sub 3/ ambient; RTP CMOS well anneal; RTP gate oxide; RTP source/drain anneal; high pressure N/sub 2/ ambient; rapid thermal processing; sub-half micron CMOS; submicron technology; threshold voltages; zero-topography well design; CMOS process; CMOS technology; Delay effects; Doping; Nitrogen; Process design; Rapid thermal annealing; Rapid thermal processing; Temperature; Threshold voltage;
Conference_Titel :
Electron Devices Meeting, 1991. IEDM '91. Technical Digest., International
Conference_Location :
Washington, DC, USA
Print_ISBN :
0-7803-0243-5
DOI :
10.1109/IEDM.1991.235414
