Following the Moore's law, flash memory has been aggressively scaled in the past ten years, but it is approaching the fundamental limits beyond the 16nm technology node. Besides the high cost of lithography facilities, the number of electrons stored per bit is less than 100 when using the multi level cell technology. It's difficult to distinguish the memory state without complicated error correction techniques at the expense of increased cost. In the past ten years, several emerging non-volatile memories have been widely investigated. Resistive random access memory (RRAM) has attracted the most attention because of the low power consumption, high operation speed, and simple structure is compatible to crossbar array. However, the undesired crosstalk problem may result in incorrect data reading. The crosstalk problem in crossbar RRAM may be solved by adding a selection device. Although the operation of bipolar RRAM is more stable than that of unipolar RRAM, there is no appropriate bipolar selection device available. In this thesis, we fabricate the selection device suitable for bipolar RRAM using a Ni/TiO2/Ni Metal-Insulator-Metal (MIM) structure, and investigated the effect of conditions on the selector characteristics. The observed nonlinear resistance was attributed to the Schottky barriers at the Ni/TiO2 interface. In recent years, flexible substrates have been used in many electronic products because of the advantages of light weight and compatibility to roll-to-roll process. We also fabricated the selector on a flexible polyimide substrate. Combined with the bipolar RRAM, we fabricated a vertically stacked 1S-1R structure which effectively reduced the crosstalk phenomenon in both 2×2 and 8×8 1S-1R array.