Nanohardness and Residual Stress in TiN Coatings

Luis Carlos Hernández; Luis Ponce; Abel Fundora; Enrique López; Eduardo Pérez

doi:10.3390/ma4050929

Nanohardness and Residual Stress in TiN Coatings

Materials (Basel). 2011 May 17;4(5):929-940. doi: 10.3390/ma4050929.

Authors

Luis Carlos Hernández¹, Luis Ponce², Abel Fundora³, Enrique López⁴, Eduardo Pérez⁵

Affiliations

¹ Laboratory of Laser Technology, CICATA-IPN, Altamira Unit, México C.P 89600, México. luiscar23@yahoo.com.
² Laboratory of Laser Technology, CICATA-IPN, Altamira Unit, México C.P 89600, México. guira_98@yahoo.com.
³ Institute of Science and Technology of Materials (IMRE), Havana University, La Habana, Cuba C.P 10400, México. fundora@fisica.uh.cu.
⁴ Centro de Innovación, Investigación y Desarrollo en Ingeniería y Tecnología (CIIDIT), Universidad Autónoma de Nuevo León, Monterrey, Nuevo León, México C.P. 66450, México. enlopez_73@yahoo.com.
⁵ Centro de Innovación, Investigación y Desarrollo en Ingeniería y Tecnología (CIIDIT), Universidad Autónoma de Nuevo León, Monterrey, Nuevo León, México C.P. 66450, México. eduardo.pereztj@uanl.edu.mx.

Abstract

TiN films were prepared by the Cathodic arc evaporation deposition method under different negative substrate bias. AFM image analyses show that the growth mode of biased coatings changes from 3D island to lateral when the negative bias potential is increased. Nanohardness of the thin films was measured by nanoindentation, and residual stress was determined using Grazing incidence X ray diffraction. The maximum value of residual stress is reached at -100 V substrate bias coinciding with the biggest values of adhesion and nanohardness. Nanoindentation measurement proves that the force-depth curve shifts due to residual stress. The experimental results demonstrate that nanohardness is seriously affected by the residual stress.

Keywords: nanohardness; nanoindentation; negative substrate bias potential; residual stress.