Ld. Madsen et al., ANALYSIS OF THE STRESS AND INTERFACIAL REACTIONS IN PT TI/SIO2/SI FORUSE WITH FERROELECTRIC THIN-FILMS/, Journal of electronic materials, 27(5), 1998, pp. 418-426
The microstructure of the Pt/Ti/SiO2/Si structure has been investigate
d by scanning and transmission electron microscopy. Pt films of 100 nm
thickness deposited by sputtering or evaporation onto unheated substr
ates gave complete coverage of the underlying Ti layer and showed a gr
anular and faceted structure with grains similar to 20 nm in diameter.
They did not exhibit hillocks or surface TiOx formation. X-ray diffra
ction was used to examine the film stress through use of the sin(2) ps
i method with bulk values for the elastic constants (v = 0.39, E = 162
GPa). The as-deposited sputtered film had a compressive stress of sim
ilar to 540 MPa, while the evaporated films had tensile stresses of si
milar to 630 MPa. The films then received a 400 degrees C rapid therma
l anneal (RTA) for 90 s and a subsequent RTA of 650 degrees C for 30 s
. Further investigation of the film stresses and microstructure were m
ade after each annealing step. After the low temperature anneal, the f
ilm stress for the sputtered film became tensile. Plan-view sections e
xamined by transmission electron microscopy (TEM) showed that the as-d
eposited sputtered films were dense but became porous after annealing.
Initially, the evaporated films had a less dense microstructure, but
were more stable with annealing. Little change in the stress for the e
vaporated film was observed after this initial low temperature anneali
ng step. Additional annealing of the evaporated and sputtered samples
caused complete consumption of the Ti layer including some TiOx format
ion from the underlying SiO2 layer and marked interaction with the Pt;
however, Little change in the stress was found. The surface of the Pt
film revealed larger grains, but otherwise remained unaffected. The u
nderlying phase changes were minimized once the Ti layer had reacted w
ith the Pt. Due to the ratio of the layers, Pt:Ti of 2:1, the surface
of the Pt was unaffected.