The adhesion of polyamide 6 (PA6)
and polyethylene (PE) toward an aluminum alloy (Al-A) and a dual phase
steel (DPS) is studied by contact angle (CA) measurements and atomic
force microscopy (AFM). With the combination of the two methods the
adhesion properties on a macro- and (sub)microscopic scale can be
determined in a nondestructive way. The work of adhesion per area
(<i>W</i><sub>ad</sub>) of the studied metal/polymer hybrids
qualitatively scales the same on both length scales, that is, Al-A/PA6
> DPS/PA6 > Al-A/PE, DPS/PE. The polymer dominates the adhesion.
The lower adhesion for PE toward the metal surfaces is explained by
dominating van der Waals attraction forces, whereas adhesion for PA6
can also be attributed to attractive polar forces such as hydrogen
bonding. For metal/PA6, <i>W</i><sub>ad</sub> on a macro-
and microscopic length scale is similar. For metal/PE, a discrepancy
is measured with lower adhesion values on the microscopic scale than
on the macroscopic scale
