Herein the edge effect from the traction-free boundary condition is utilized to direct the spontaneous surface wrinkling. This boundary condition is attained by a simple combination of mechanical straining and selective exposure of polydimethylsiloxane (PDMS) substrate to O-2 plasma (OP) through a copper grid. When the strained PDMS sheet is subjected to selective OP treatment, a patterned heterogeneous surface composed of the OP-exposed "hard" oxidized, SiOx region (denoted as D-1) and the OP-unexposed "soft" region (denoted as D-2) is produced The subsequent full release of the prestrain (epsilon(pre)) leads to the selective wrinkling in D-1 rather than in D-2. It is seen that even in D-1, no wrinkling occurs in the vicinity of the D-1 edge that is perpendicular to the wavevector. Furthermore, the average wrinkle wavelength in D-1 (lambda(D1)) is smaller than that of the exposed copper grid free blank area (lambda(blank)). This wavelength decrement between lambda(D1) and lambda(blank), which can be used to roughly estimate the edge effect extent, increases with the applied mesh number of copper grids and exposure duration, while decreases with the increase of epsilon(pre). Meanwhile, there exists a decrease in the amplitude of the patterned wrinkles, when compared with that of the blank region. Additionally, hierarchical wrinkling is induced when the strain free PDMS substrate is selectively exposed to OP, followed by uniaxial stretching and the subsequent blanket exposure. Consequently, oriented wrinkles perpendicular to the stretching direction are generated in D-2. With respect to D-1, no wrinkling happens or orthogonal wrinkles occur in this region depending on the applied mesh number, exposure duration, and epsilon(pre). In the above wrinkling process, the combinative edge effects in two perpendicular directions that are involved sequentially have been discussed.