Title :
Electromagnetic annealing for the 100 nm technology node
Author :
Thompson, K. ; Booske, J.H. ; Gianchandani, Y.B. ; Cooper, R.F.
Author_Institution :
Wisconsin Univ., Madison, WI, USA
fDate :
3/1/2002 12:00:00 AM
Abstract :
Electromagnetic induction heating (EMIH) is a novel rapid thermal processing technique that uses microwave and radio frequency (RF) radiation to directly heat silicon wafers. Heating rates of 125/spl deg/C/s have been achieved and 75 mm diameter wafers have been heated above 1000/spl deg/C using only 950 W of power. EMIH has been used to activate shallow implanted dopants with minimal diffusion of the junction depth. It is speculated that the exposure of the wafer to intense electric fields during the anneal may provide an additional driving force for dopant activation, allowing for higher activation at lower temperatures. Post-anneal junction depths less than 25 nm with sheet resistances between 700 and 1000 ohms/square have been achieved without the use of a controlled low oxygen ambient. The EMIH Rs-Xj curve penetrates the SEMATECH 100 nm technology box and with further optimizations may satisfy the 70 nm technology node.
Keywords :
doping profiles; elemental semiconductors; induction heating; integrated circuit technology; microwave heating; nanotechnology; process heating; radiofrequency heating; rapid thermal annealing; semiconductor technology; silicon; 100 nm; 100 nm technology node; 1000 degC; 25 nm; 70 nm; 75 mm; 950 W; RF radiation; RTP; Si wafers; electromagnetic annealing; electromagnetic induction heating; implanted dopant activation; intense electric fields; microwave radiation; radiofrequency radiation; rapid thermal processing technique; shallow implanted dopants; wafer heating; Annealing; Electromagnetic heating; Electromagnetic radiation; Magnetic flux; Magnetic resonance; Radio frequency; Rapid thermal processing; Silicon; Steady-state; Temperature control;
Journal_Title :
Electron Device Letters, IEEE
