Resistive random access memory (RRAM) has become one of the most promising emerging memories due to its low power consumption, fast speed and simple structure. In recent years, the crossbar array is adopted for ultra-high density memories. However, the crosstalk effect would cause read interference of the memory state. To solve this problem, RRAM should be connected with a selection device. Previously our group has successfully demonstrated metal-insulator-metal (MIM) devices, including the unipolar diode and bipolar selector, applicable for the one diode-one resistor (1D1R) and one selector-one resistor (1S1R) arrays, respectively. The performance of the selection devices is judged by nonlinearity factor and maximum current density. To enhance these two factors, thorough understanding of the current conduction mechanism in the MIM structures is essential. This research focuses on the TiO2-based selection devices using different metal top electrodes. We measured their current-voltage curves and then fitted to various current conduction mechanisms. Furthermore, we varied the defect concentration at the top electrode/TiO2 interface using additional oxygen gettering layers and discovered significant changes in IV characteristics. This result supported that modulating the interface defect concentration is a feasible way to enhance nonlinearity and current density of nonlinear MIM selectors. Besides, we also measured various devices using a pulse IV setup and discovered that the current density is lower using higher frequency pulse. This result is related to the ionization rate of oxygen vacancies. Furthermore, we conducted temperature-dependent pulse IV measurement using fixed pulse base time and various pulse widths. Finally, a simple physical model is proposed to explain the results qualitatively.