Arsenic redistribution induced by low-temperature Ni silicidation at 450°C on shallow junctions

Abstract

Redistribution of arsenic (As) during silicidation of a 13-nm Ni film on an n+/p junction at 450°C is investigated. NiSi formation is observed by x-ray diffraction, micro-Raman scattering spectroscopy, and Rutherford backscattering spectroscopy (RBS). Both secondary ion mass spectroscopy and RBS data indicate the redistribution and accumulation of As into two layers after the low-temperature annealing. The deeper accumulation peak, located just near the silicide/silicon interface, is attributed to As segregation from silicide into Si substrate. The shallower accumulation peak is located in a vacancy-cluster layer several nanometers below the silicide film surface. The vacancy-cluster layer, characterized by cross-sectional transmission electron microscopy, separates the silicide film into two layers, and is attributed to the well-known Kirkendall effect.