Force-distance curves were obtained using a home-built atomic force microscope (AFM) at different temperatures (T = 30-65 degrees C) and probe rates (f = 31.25-50 000 Hz) on a 150 nm thick film of a model sample, poly(tert-butyl acrylate) (M-w = 148K Da, M-w/M-n = 17, and T-g(bulk) = 50 degrees C according to DSC). The pull-off force, F-ad, at which detachment between the AFM tip and the sample occurred was measured as adhesion. By limiting the loading force, F, to similar to 2.5 nN, the tip penetrated by no more than 2 nm into the sample in the glassy state. Therefore, evolution of the rheological properties of the polymer at the free surface with increasing T could be studied. In the vicinity of T-g(bulk), F-ad was seen to increase rapidly with increasing T or decreasing f. Equivalence between T and f was found using time-temperature superposition in which, upon rescale off by a temperature-dependent shift factor a(T)(AFM)(T), a master curve F-ad(alpha(T)(AFM)(T) f) resulted. We showed that F-ad(alpha(T)(AFM)(T)f) could be fully accounted for by using an approach based on fracture mechanics of viscoelastic solids. No noticeable enhancement in the surface relaxation could be deduced according to our findings.