Thermal conductivity of nitride films of Ti,Cr,and W deposited by reactive magnetron sputtering

Author:

Jagannadham, Kasichainula  

Journal:

JOURNAL OF VACUUM SCIENCE & TECHNOLOGY A

Issue Date:

2015

Abstract(summary):

Nitride films of Ti, Cr, and W were deposited using reactive magnetron sputtering from metal targets in argon and nitrogen plasma. TiN films with (200) orientation were achieved on silicon (100) at the substrate temperature of 500 and 600 degrees C. The films were polycrystalline at lower temperature. An amorphous interface layer was observed between the TiN film and Si wafer deposited at 600 degrees C. TiN film deposited at 600 degrees C showed the nitrogen to Ti ratio to be near unity, but films deposited at lower temperature were nitrogen deficient. CrN film with (200) orientation and good stoichiometry was achieved at 600 degrees C on Si(111) wafer but the film deposited at 500 degrees C showed cubic CrN and hexagonal Cr2N phases with smaller grain size and amorphous back ground in the x-ray diffraction pattern. An amorphous interface layer was not observed in the cubic CrN film on Si(111) deposited at 600 degrees C. Nitride film of tungsten deposited at 600 degrees C on Si(100) wafer was nitrogen deficient, contained both cubic W2N and hexagonal WN phases with smaller grain size. Nitride films of tungsten deposited at 500 degrees C were nonstoichiometric and contained cubic W2N and unreacted W phases. There was no amorphous phase formed along the interface for the tungsten nitride film deposited at 600 degrees C on the Si wafer. Thermal conductivity and interface thermal conductance of all the nitride films of Ti, Cr, and W were determined by transient thermoreflectance technique. The thermal conductivity of the films as function of deposition temperature, microstructure, nitrogen stoichiometry and amorphous interaction layer at the interface was determined. Tungsten nitride film containing both cubic and hexagonal phases was found to exhibit much higher thermal conductivity and interface thermal conductance. The amorphous interface layer was found to reduce effective thermal conductivity of TiN and CrN films. (C) 2015 American Vacuum Society.