Title :
Channeling effect and energy contamination evaluations of B-based beam-line ULE implants - Tools and recipe set-up dependence
Author :
Shu Qin ; Hu, Yongjun Jeff ; McTeer, Allen
Author_Institution :
Micron Technol. Inc., Boise, ID, USA
fDate :
June 26 2014-July 4 2014
Abstract :
We extensively investigate tool and recipe set-up dependence of the ultra-shallow junctions (USJ) doped by the boron-based ultra-low energy (ULE) beam-line (BL) implants. Recipes set-up includes different tools, energies, implant temperatures, and deceleration ratios. Channeling effect and energy contamination issues are de-coupled by drift and deceleration mode implants. A channeling effect factor (CEF) is defined and quantified. Channeling effect is found to be a major factor causing deeper profiles and long tails (xj). Channeling effect gets worse when the implant energy is reduced due to less self-PAI effect (with less damage). Low temperature (-100 °C) implant does not effectively reduce channeling effect. Deceleration mode implant increases tail (xj) due to energy contamination as a secondary order effect.
Keywords :
boron; doping profiles; ion implantation; semiconductor doping; beamline ULE implants; channeling effect factor; deceleration mode implants; deceleration ratio; energy contamination evaluation; low temperature; temperature -100 degC; ultra-low energy beamline implants; ultra-shallow junctions; Contamination; Doping; Implants; Junctions; Semiconductor device modeling; Silicon; Temperature; channeling effect; energy contamination; ultra-low energy (ULE) implant; ultra-shallow junction (USJ);
Conference_Titel :
Ion Implantation Technology (IIT), 2014 20th International Conference on
Conference_Location :
Portland, OR
DOI :
10.1109/IIT.2014.6939958
