Surface energy of nylon 66 fibers is of considerable importance in the
conversion of these fibers into consumer products such as tirecord, c
arpets, and various composite materials in combination with other poly
mers. Adhesion of nylon 66 fibers to rubber or the coupling agent in t
irecord, or to the fluoropolymer used as a soil resist finish in carpe
ts, depends on the surface energy of these fibers, If produced undrawn
, nylon 66 fibers can be drawn later, up to 8x, to attain desirable fi
ber properties. Since hydrogen bonds rearrange during drawing it would
be of interest to see if these changes also result in changes in surf
ace energy. An attempt has been made to understand this aspect in this
article, We have determined the dispersion and the acid-base (donor-a
cceptor) components of the surface energy of nylon 66 fibers by wettab
ility measurements in appropriate probe liquids using the Wilhelmy pri
nciple, as well as by inverse gas chromatography (IGC), where interact
ions between the fiber surface and the probe molecules are studied in
a chromatography column in which fibers form the stationary phase. By
suitable data treatment these chromatograms could be converted to adso
rption isotherms. The probe molecules were reasonably well matched to
give comparable values by the two methods, Adsorption of site-specific
fluorescent dyes showed increases in acid and basic surface groups by
microfluorometry on drawn fibers. The density of the surface groups d
epended on the drawing environment, especially the one involving liqui
d water, The apparent discrepancy between microfluorometry results and
the surface energy by wettability measurements resolved itself when t
he surface energy components were calculated by assuming that the enti
re work of adhesion results from hydrogen bonding interactions only, i
n solids with functional groups capable of forming strong hydrogen bon
ds, such as nylons,as suggested by Gutowski. (C) 1996 Academic Press,
Inc.