Title :
Stress Analysis and Junction Leakage of Sub-Melt Laser Annealed SiGe Epitaxial Layers
Author :
Gonzalez, Mireia Bargallo ; Rosseel, Erik ; Hikavyy, Andriy ; Fernandez-Lanas, Tatiana ; Eneman, Geert ; Verheyen, Peter ; Loo, Roger ; Simoen, Eddy ; Claeys, Cor
Author_Institution :
Interuniversity Microelectron. Center, Leuven, Belgium
Abstract :
The purpose of this paper is to study the impact of the different post-epi process steps on the stress behavior of epitaxially grown Si1-x-Gex layers on Si substrates and the subsequent defectivity and device leakage. Stress measurements were performed by the in-line monitoring laser reflectance method to further investigate the intrinsic film stress dependence on the ion implantation conditions (atom size, depth of the implant, and dose) and the laser scan energy beam conditions during dopant activation (temperature, dwell time, and power). Moreover, the role of the millisecond laser anneal conditions on the area leakage current of embedded SiGe source/drain junctions is discussed. The analysis is complemented with structural characterization based on Nomarski microscopy.
Keywords :
CMOS integrated circuits; Ge-Si alloys; MOSFET; ion implantation; laser beam annealing; leakage currents; semiconductor epitaxial layers; semiconductor growth; semiconductor materials; stress analysis; CMOS technologies; Nomarski microscopy; Si; SiGe; device leakage; dopant activation; embedded source-drain junctions; epitaxial grown layers; in-line monitoring laser reflectance method; intrinsic film stress dependence; ion implantation conditions; junction leakage; laser scan energy beam conditions; millisecond laser anneal conditions; nMOS transistors; pMOS transistors; post-epi process; stress analysis; structural characterization; submelt laser annealed epitaxial layers; Annealing; Atom lasers; Condition monitoring; Epitaxial layers; Germanium silicon alloys; Performance evaluation; Power lasers; Silicon germanium; Stress measurement; Substrates; Embedded SiGe; extended defects; junction leakage current; millisecond laser anneal; strain engineering;
Journal_Title :
Semiconductor Manufacturing, IEEE Transactions on
DOI :
10.1109/TSM.2010.2050789
