Asymmetrically structured porous materials with controlled mechanical or chemical properties have been extensively studied and applied to adsorbents, heterogeneous catalysts, membrane filtration systems, surface hydrophobic modification, drug loading and delivery. Here we reported an innovative method for the fabrication of asymmetrical porous structures based on a vapor-phased sublimation and deposition process. The fabricated materials exhibited versatility and advantages being well-controlled pores structures and functional properties from an asymmetrical distribution. By using a time dependent customization parameter to control the bulk size or the dispersion of molecules, the fabrication of materials were demonstrated to produce particles with asymmetrical pores structure and with bulk size ranging from >500 µm to submicron. The particles were constructed via vapor depositions of poly-p-xylylenes on sublimating solid template. Pore structure was formed by the releasing sublimated vapor of the solid template disrupted poly-p-xylylene deposition and polymerization, thus allowing the control of porosity by modulating the sublimation speed of the template. Also according to the sublimation and interface properties of liquids, we got the stable composite as the sublimation template by freezing, and the proposed poly-p-xylylene particles is prepared subsequently by vapor sublimation/deposition mechanism to yield asymmetrical porous structure caused by the sublimated vapors and the non-sublimable liquid during the fabrication process. And the functional substances were confined within the structural materials based on a timed solidification of mass transport in transient regime and were observed through the fluorescence signals. The proposed functional asymmetrical materials were constructed and assembled in vapor phase and in one step, and prospective materials produced by the method with novel properties are expected with unlimited applications.