This paper explores the interfacial properties of one-dimensional molecular gradients of alkanethiols (HS–(CH₂)_n–X) on gold. The kinetics and thermodynamics of monolayer formation are important issues for these types of mixed molecular assemblies. The influence of chain length difference on the contact angles with hexadecane (HD), θ_a and θ_r, and the hysteresis, has been studied by employing alkanethiols HS–(CH₂)_n–CH₃, with n=9, 11, 13, 15 and 17, in the preparation of the self-assembled monolayers (SAM) gradients. The contact angles with hexadecane, at the very extreme ends of the gradients, show characteristic values of a highly ordered CH₃-like assembly: θ_a=45–50°. In the middle of the gradients θ_a drops noticeably and exhibits values representative for CH₂-like polymethylenes, θ_a=20–30°, indicating a substantial disordering of the protruding chains of the longer component in the gradient assembly. As expected, the exposure of CH₂-groups to the probing liquid increases with increasing differential chain length of the two n-alkanethiol used, in this case eight methylene units. However, the contact angles always display a non-zero value which means that even at a chain length difference of eight methylene units there is a substantial exposure of methyl (CH₃) groups to the probing liquid. With infrared reflection-absorption spectroscopy (IRAS) we have monitored the structural behavior of the polymethylene chains along the gradient. We find complementary evidence for disordered chains in the gradient region, and the IRAS results correlate well with the contact angle measurements.