The aim is to measure in-situ the growth rate and final thickness of thin f
ilms of SnO2 and SnO2:F (by oxidation of (CH3)(2)SnCl2) deposited on a glas
s substrate, using an Atmospheric Pressure Chemical Vapour Deposition (APCV
D) lab-scale reactor. The measuring system uses an optical technique: based
on thin-film interference (Fresnel equations and the matrix analysis of th
em). At the same time, an FTIR spectrophotometer has been installed, analys
ing the composition of the gas phase species in the reaction zone (in-situ)
. Changes in the intensity of the reflectivity at each wavelength were reco
rded in the visible range, during the growth of the film. Assuming that the
film is transparent in the visible range, the optical film thickness can b
e monitored For each wavelength as the film grows. Hence the film thickness
can be calculated assuming the refractive index is known, and does not var
y during deposition. A program was developed that reads the spectra vs. tim
e, and translates the data into thickness vs, time for each wavelength. The
final value is the median of all wavelengths. Correlations between the dif
ferent species involved in the gas phase, the resistivity, emissivity and t
he growth parameters have been investigated.