In this thesis, a resistive random-access memory was fabricated by using the nickel oxide, grown by thermal evaporation followed by an annealing process at different temperatures, as the dielectric layer sandwiched between the p-type silicon substrate and the aluminum contact. Atomic force microscopy and X-ray diffraction analysis were carried out for the investigation on the surface morphology and the crystalline structure of the grown nickel oxide, respectively. It was revealed that the annealing temperature and the oxygen flow were crucial to the electrical property of the nickel oxide layer. From the experimental results, it was found that the values of high-resistive and low-resistive states will increase with the incremental annealing temperature but decrease with the increasing oxygen flow rate at the optimized annealing temperature. It was also observed that the surface morphology is the key factor for stabilizing the operation of the resistive random-access memory. The results indicated that a nickel oxide film with a rougher surface morphology will greatly improve the lifetime and the reliability of the device. Resistive random-access memory is presently a developing subject for solid state devices and aimed to replace dynamic random-access memory and flash memory. The results in this thesis indicate that the stability and persistence of the resistive random-access memory devices will be the fundamental challenges for its future development.