Title :
Submicrometer CMOS device fabrication using gas immersion laser doping (GILD)
Author :
Weiner, K.H. ; Sigmon, T.W.
fDate :
12/1/1988 12:00:00 AM
Abstract :
The first successful fabrication of submicrometer CMOS devices using the gas immersion laser doping (GILD) process. It consists of placing a suitably masked silicon wafer in a gas cell containing the desired dopant gas and then incorporating the dopant species in one or more melt/regrowth steps initiated by a XeCl (λ=308 nm) pulsed excimer laser. High-quality ultrashallow (200-to-1500-Å) n+ /p and p+/n junctions with concentrations of >4×1020 cm-3 for n+ and >5×1021 for p+ result from this process. In addition, ideal diode behavior for forward bias and low leakage currents (IR<10 nA-cm-2 at -5 V) for reverse bias are observed for unannealed junctions formed by the GILD process, a result with potential advantages for future ULSI processing. The first implementation of laser doping in a CMOS process is also reported. Excellent device characteristics are obtained on devices that have not received any thermal processing about 380°C following formation of the source/drain region
Keywords :
CMOS integrated circuits; VLSI; integrated circuit technology; laser beam annealing; laser beam applications; semiconductor doping; -5 V; 20 to 380 C; 200 to 1500 A; 308 nm; GILD; XeCl excimer laser; device characteristics; dopant gas; fabrication; forward bias; future ULSI processing; gas cell; gas immersion laser doping; ideal diode behavior; laser annealing; low leakage currents; masked Si wafer; melt/regrowth steps; pulsed excimer laser; reverse bias; submicrometer CMOS devices; submicron; ultrashallow p-n junctions; unannealed junctions; CMOS technology; Diodes; Doping profiles; Frequency; Gas lasers; Gunn devices; Ion beams; Optical device fabrication; Silicon; Wafer bonding;
Journal_Title :
Electron Devices, IEEE Transactions on
