Title :
Process dependence of 0.11 μm RF CMOS on high-resistivity substrate for System on Chip (SOC) application
Author :
Ohguro, T. ; Kojima, K. ; Momo, N. ; Momose, H.S. ; Toyoshima, Y.
Author_Institution :
Center for Semicond. R&D, Toshiba Corp., Yokohama
fDate :
June 17 2008-April 17 2008
Abstract :
High-resistivity substrate with beyond 1000 ohm-cm realizes high performance in terms of inductor, antenna, MIM capacitor and substrate noise for high- frequency applications. However, this wafer has serious problems for mixed-signal, RF and digital circuits. Those are reduction of high resistivity during sinter process such as 400degC, larger leakage current between nwells, extreme lower snap-back voltage in latch-up behavior and higher RF noise. The RF noise is proportional to square root of Si substrate resistivity in our experience. In this paper, it is shown that these problems can be resolved by the optimum wafer fabrication process and the additional ion implantation.
Keywords :
CMOS integrated circuits; radiofrequency integrated circuits; system-on-chip; MIM capacitor; RF CMOS; RF noise; antenna; high-frequency application; high-resistivity substrate; inductor; ion implantation; latch-up behavior; leakage current; optimum wafer fabrication process; process dependence; sinter process; size 11 micron; snap-back voltage; substrate noise; system on chip application; CMOS process; Circuit noise; Conductivity; Digital circuits; Inductors; Leakage current; MIM capacitors; Radio frequency; System-on-a-chip; Voltage; RF noise; high Q inductor; high- gain antenna; high-resistivity substrate; mm-Wave application; oxygen predicted wafer; snap-back voltage;
Conference_Titel :
Radio Frequency Integrated Circuits Symposium, 2008. RFIC 2008. IEEE
Conference_Location :
Atlanta, GA
Print_ISBN :
978-1-4244-1808-4
Electronic_ISBN :
1529-2517
DOI :
10.1109/RFIC.2008.4561499
