In this study, poly(styrene-co-acrylonitrile) (SAN) and dual solvents system was used to produce micron-sized fibers with different morphologies by different phase separation methods during electrospinning. The selection and ratio of the solvents affect the dominant phase separation mechanism, resulting in electrospun fibers with surface macroporous or internal small pore structures. In addition to solvent pair and solvent ratio, polymer solution, environmental parameters and processing parameters also affect the fiber morphology. Therefore, the following parameters were manipulated in the experiment: solvent pair, solvent ratio, polymer concentration, ambient relative humidity, feed flow rate, voltage, and salt additives. In the past, the pre-mixed polymer/good solvent/nonsolvent ternary solution was mostly used for fabricating surface porous fibers. In this study, however, we found that in the dual good solvent system, when the lower boiling point solvent is immiscible with water and the higher boiling point solvent is soluble with water, the fibers with surface pores can also be produced at specific solvent ratio. Water is a non-solvent for the polymer. The key point is that water from the surrounding air condenses on the fiber jets surface, the higher boiling point hydrophilic solvent can diffuse into the condensed water droplets to induce phase separation and cause larger surface pores. Both hydrophilic solvent and water are very important experimental variables, so we proposed a new phase separation mechanism - Hydrophilic Solvent Assistant Breath Figure (HSABF). The best solvent pair can form surface macroporous fibers with excellent properties, with the fiber contact angle reaching 151° and demonstrating superhydrophobic properties. In the oil adsorption experiment, we prepared porous fibers with 1 µm diameter, which show the best performance on oil adsorption. The adsorption capacity in silicone oil could reach 228 g/g, which was 4 times higher than the adsorption capacity of non-porous fibers with 3 µm diameter.