Dynamic surface anneal: activation without diffusion

Author

Jennings, Dean ; Mayur, Abhilash ; Parihar, Vijay ; Liang, Haifan ; Mcintosh, Robert ; Adams, Bruce ; Thomas, Tim ; Ranish, Joe ; Hunter, Aaron ; Trowbridge, Teresa ; Achutharaman, Raman ; Thakur, Randhir

fYear

2004

fDate

2004

Firstpage

47

Lastpage

51

Abstract

The continued scaling of devices in accordance with Moore´s law requires activation of some implants such as the source-drain extensions, SDEs, with as little diffusion as possible. New options in thermal processing are described and compared. Thermal flux annealing is the regime where power density is high enough to cause local heating but not so high as to eliminate heat transfer entirely. If energy is delivered fast enough, i.e.: the power density is high enough, the surface of the wafer can reach useful annealing temperatures before the bulk temperature rises appreciably. Limited heat transfer enables the substrate as a heat sink for rapid device region cool down. Thermal homogenization on the device scale also occurs when the thermal diffusion length is a few tens of microns. Wavelengths for scanning laser are compared as well as broadband flash lamp annealing

Keywords

annealing; elemental semiconductors; silicon; surface treatment; thermal diffusion; Moore law; Si; dynamic surface anneal; flash lamp annealing; heat transfer; power density; source-drain extensions; thermal flux annealing; thermal homogenization; Absorption; Gas lasers; Heat sinks; Heat transfer; Implants; Rapid thermal annealing; Semiconductor laser arrays; Silicon; Temperature dependence; Thermal conductivity;

fLanguage

English

Publisher

ieee

Conference_Titel

Advanced Thermal Processing of Semiconductors, 2004. RTP 2004. 12th IEEE International Conference on

Conference_Location

Portland, OR

Print_ISBN

0-7803-8477-6

Type

conf

DOI

10.1109/RTP.2004.1441892

Filename

1441892