An Analytic Equation for Assessing the Thickness of Titanium Nitride Coatings by Energy Dispersive X-ray Spectroscopy in the Scanning Electron Microscope

In this study, a methodology for assessing the thickness of titanium nitride (TiN) coatings by energy dispersive X-ray spectroscopy (EDS) in the scanning electron microscope is explored. A standardless method is applied, where the film thickness (th) is related to the microscope accelerating voltage (V-0), the type of substrate and the ratio between the more intense peaks in the EDS spectrum, arising from both the substrate and the coating (afterwards called the I-ratio, I-R). Three different substrates covered with TiN were studied, namely, silicon, glass, and stainless steel. Monte Carlo simulations enabled to state an analytic equation, which allows assessing the coating thickness as follows: th = th(cr) center dot exp[ - beta I(R)1/n] where I-R = I-ksubstrate/I-kcoating, th(cr) (critical thickness) is the largest coating thickness, which is assessable at a fixed V-0, beta is a multiplication factor, and n is an exponent, where th(cr), beta and n are assessable from V-0 and substrate type. Interpolation via the equation presented, using reference thicknesses, allowed thickness predictions with around 80% of datapoints differing less than around 2% from the reference value. A procedure for detecting variations as low as 1.0% in coating thickness regarding the nominal thickness is presented.