Effects of deposition methods on the temperature-dependent resistivity of tungsten films
The resistivity of tungsten films prepared by magnetron sputtering, electron gun evaporation, and chemical vapor deposition was measured in the 4.2--297 K temperature range. The resistivity rho in all films decreases linearly with temperature down to 60 K, indicating that scattering by lattice phonons is responsible for most of the resistivity at higher temperatures. Residual resistivity decreases with increasing grain size as determined from transmission electron microscopy (TEM). Residual resistivity ratio (RRR) values are in the 2--7 range and this includes the epitaxially grown film investigated for comparison. Annealing, in general, increases RRR and in the case of epifilm, a value of 20.5 is obtained after 1000 /sup 0/C anneal. The temperature coefficient of resistivity is found to decrease with increasing rho/sub 297 K/, reflecting a growing contribution from defects and impurities. The effect of impurities is interpreted in terms of the grain boundary scattering model with reflection coefficient R, varying with deposition technique and thus with the amount of impurities incorporated in the films. Evaporated films have R less than 0.4, suggestive of low impurity content. In these films, defects observed in TEM play a major role. Cracks, precipitates, and dislocation loops contribute more significantly to rho/sub 4.2 K/ than to rho/sub 297 K/. The contribution of defects can be reduced by raising substrate temperature ( rho/sub 297 K/ = 6.39 ..mu cap omega.. cm) or by anneal at 1000 /sup 0/C.
- Research Organization:
- IBM T. J. Watson Research Center, Yorktown Heights, New York 10598
- OSTI ID:
- 7141414
- Journal Information:
- J. Vac. Sci. Technol., A; (United States), Vol. 4:6
- Country of Publication:
- United States
- Language:
- English
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Related Subjects
TUNGSTEN
ELECTRIC CONDUCTIVITY
SURFACE COATING
CHEMICAL VAPOR DEPOSITION
CRYSTAL DEFECTS
DEPOSITION
EPITAXY
EVAPORATION
FILMS
GRAIN SIZE
IMPURITIES
PHONONS
SPUTTERING
TEMPERATURE DEPENDENCE
TRANSMISSION ELECTRON MICROSCOPY
VACUUM COATING
CHEMICAL COATING
CRYSTAL STRUCTURE
ELECTRICAL PROPERTIES
ELECTRON MICROSCOPY
ELEMENTS
METALS
MICROSCOPY
MICROSTRUCTURE
PHASE TRANSFORMATIONS
PHYSICAL PROPERTIES
QUASI PARTICLES
SIZE
TRANSITION ELEMENTS
360104* - Metals & Alloys- Physical Properties